JP2004141758A - Method of correcting dot position of droplet discharge device, alignment mask, droplet discharge method, electro-optical device and its production method, and an electronic equipment - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a method of correcting the dot position of a droplet discharge device which can precisely discharge functional droplets to a work irrespective of the mechanical precision of an X/Y moving mechanism etc., an alignment mask, a droplet discharge method, an electro-optical device and its production method, and an electronic equipment. <P>SOLUTION: In order to correct the dot position, first, in relation to each inspection area Q formed in the shape of the lattice of the alignment mask 50, and a drawing action based on discharge pattern data for alignment is done to draw two dots for inspection. After that, the positional dislocation of the dots for inspection in relation to a normal dot position regulated by the standard mark 58 of each inspection area Q is image-recognized. Next, the discharge pattern data for implementing the drawing action based on two displacement data are corrected. If required in the drawing action, angle correction data for rotating a droplet discharge head 6 in the surface are prepared. <P>COPYRIGHT: (C)2004,JPO

Description

と求められる。なお、ｘ＋ｙ＝ｕ＋ｖ＝３０（ｍｍ）である。同様にして、点ＰａのＹ軸補正データおよびΘ軸補正データが求められる。
【００９８】
ステップＳ５における吐出パターンデータの補正は、Ｘ・Ｙ・Θ軸に関する複数の補正データのうち、複数のＸ軸補正データおよび複数のＹ軸補正データ（いずれも、格子点Ｐ以外の補正データを含む）を用いてノズル列４５毎に行われる。具体的には、吐出パターンデータには、液滴吐出ヘッド６の吐出駆動に関する吐出タイミングデータと、Ｘ・Ｙ移動機構２による基板Ｗに対する液滴吐出ヘッド６の相対移動に関するヘッド移動パターンデータとが含まれており、複数のＸ軸補正データを基にヘッド移動パターンデータを補正し、複数のＹ軸補正データを基に吐出タイミングデータを補正している。
【００９９】
これにより、Ｘ軸方向（副走査方向）のドット位置のずれは、主走査する液滴吐出ヘッド６（メインキャリッジ５）がＸ軸方向に適宜微少移動することで、解消される。一方、Ｙ軸方向（主走査方向）のドット位置のずれは、液滴吐出ヘッド６の吐出タイミングをずらすことで、解消される。
【０１００】
この場合、吐出タイミングをずらす補正は、描画データを展開する位置（アドレス）を変更することにより行われる。上述のようにＹ軸リニアエンコーダが０．１μｍの精度で読取り可能であるため、Ｙ軸方向には０．１μｍ単位で描画データを展開できることから、例えば、Ｙ座標０ｍｍのアドレスが「０００００」、Ｙ座標１ｍｍのアドレスが「１００００」、Ｙ座標１０ｍｍのアドレスが「１０００００」であるとする。この場合に、Ｙ座標１０ｍｍのポイントでＹ軸補正データが「−１μｍ」である場合、すなわちドットがＹ座標１０ｍｍの１μｍ手前で描画される場合、このポイントにおける描画データを展開するアドレスを「１００００１」と変更することで、吐出タイミングデータが補正される。
【０１０１】
このようにして、液滴吐出ヘッド６の描画動作に適した態様で、吐出パターンデータの補正が行われた後、補正後の吐出パターンデータおよびΘ軸補正データに基づいて、基板Ｗに対する本描画動作が行われることになる。
【０１０２】
ここで、本描画動作の単純な例について、図８を参照して説明する。図３に示した格子点Ｐ００の座標を（Ｘ，Ｙ）＝（０，０）ｍｍ、格子点Ｐ０１の座標を（０，３０）ｍｍ、格子点Ｐ０２の座標を（０，６０）ｍｍとし、各格子点Ｐ００，Ｐ０１，Ｐ０２の補正データは、図８に示したものとする。この場合、上記の式（１）は、
【数２】

と変形できる。
【０１０３】
したがって、例えば、Ｙ軸方向に１０ｍｍ単位で補正を実行しながら本描画動作を行うとすると、式（２）に示す「ｕ」と「ｖ」との関係から、Ｙ座標１０ｍｍおよびＹ座標２０ｍｍのポイントでは、格子点Ｐ００および格子点Ｐ０１のＸ軸補正データの差の１／３の値がそれぞれ補正されるように、液滴吐出ヘッド６のＸ軸方向への微少移動が行われることになる。
【０１０４】
同様に、二つの格子点Ｐの間のＹ座標の各ポイントでは、二つの格子点ＰのＹ軸補正データの差の１／３の値がそれぞれ補正されるように、液滴吐出ヘッド６の吐出タイミングが変更されて行われると共に、二つの格子点ＰのΘ軸補正データの差の１／３の値がそれぞれ補正されるように、ヘッド角度微調整機構３４により液滴吐出ヘッド６のΘ軸方向への微少回転が行われる。なお、同図（ｃ）に示す「α」は、液滴吐出ヘッド６の回転による１番ノズルのＸ軸方向移動分を考慮して図示したものである。
【０１０５】
以上のように、液滴吐出装置１では、実際にＸ・Ｙ移動機構２および液滴吐出ヘッド６を駆動して、アライメントマスク５０への描画結果から吐出パターンデータを補正し、補正後の吐出パターンデータおよびΘ軸補正データに基づいて、基板Ｗへの実際の描画動作を行っている。これにより、仮にＸ・Ｙ移動機構２に構造上の歪み等があったとしても、これを適切に解消する描画動作となるため、ドット位置精度の高い描画を実現することができる。
【０１０６】
なお、ヘッド角度微調整機構３４とＸ・Ｙ移動機構２とにより、請求項にいうＸ・Ｙ・Θ移動機構を構成したが、ヘッド角度微調整機構３４に代えて、基板Ｗ（ワーク）をΘ軸方向に回転させるワーク回転機構を設け、ワーク回転機構とＸ・Ｙ移動機構２とにより、上記のＸ・Ｙ・Θ移動機構を構成してもよい。この場合には、ワークテーブル９の回転機構が、ワーク回転機構の主要部となる。
【０１０７】
また、上記した液滴吐出ヘッド６のノズル４６数、ノズル列４５数、ノズル列４５の延在方向も任意であり、例えば、液滴吐出ヘッド６を主走査方向に対し予め所定の角度傾けたものであってもよい。もちろん、液滴吐出ヘッド６が単数のものに限らず、これらが複数の場合にあっては、その配置パターンも千鳥状配置、階段状配置など任意であるが、複数の液滴吐出ヘッド６の全吐出ノズル４６が副走査方向において連続していることが好ましい。さらに、複数の液滴吐出ヘッド６に対しても、個々に吐出パターンデータの補正を行えばよく、その際のΘ軸方向への補正については、全ての液滴吐出ヘッド６を一括して行うようにすることが好ましい。
【０１０８】
また、Ｘ・Ｙ移動機構２の老朽化等により当初の精度にずれが生じてきた場合、補正データの見直しを行うことが好ましい。その際には、当初に用いたアライメントマスク５０を液滴吐出装置１に再導入して行ってもよい。
【０１０９】
もっとも、ヘッド角度微調整機構３４を設けなくとも、Ｘ・Ｙ軸方向の２次元補正でもドット位置を補正することも十分に可能である。この場合、図５に示したステップ３の描画動作では、一つの検査エリアＱに描画する検査用ドットは一つで足り、ステップ４の画像認識では、一つの検査エリアＱにて認識するドット位置は一つで足りる。そして、複数のＸ軸補正データおよび複数のＹ軸補正データを基に、吐出パターンデータを上記と同様に補正すればよい。
【０１１０】
なお、液滴吐出装置１の吐出対象となるワークは、上記のようなガラス基板等のほか、単票紙や印刷テープなどの一般的な記録媒体であってもよい。
【０１１１】
次に、図９を参照して、第２実施形態について説明する。本実施形態の液滴吐出装置１では、液滴吐出ヘッド６はメインキャリッジ５（ヘッドキャリッジ）に搭載され、認識カメラ８はカメラキャリッジ１０１に搭載され、液滴吐出ヘッド６と認識カメラ８とは、それぞれ独立してＸ軸方向に移動可能に構成されている。
【０１１２】
また、これらキャリッジ５，１０１の移動経路に臨んでＸ軸センサ１０２が設けられ、Ｘ軸センサ１０２により、メインキャリッジ５およびカメラキャリッジ１０１の相対位置、すなわち液滴吐出ヘッド６および認識カメラ８の相対的な位置関係を直接検出することができるようになっている。さらに、図示省略するが、Ｘ軸方向のホーム位置に、液滴吐出ヘッド６のノズル面４２（の四周縁部）を受容して、液滴吐出ヘッド６の機能液吸引および保管等の保全処理を行う吸引ユニットが設けられている。
【０１１３】
本実施形態によれば、カメラキャリッジ１０２を介した認識カメラ８による画像認識動作中に、メインキャリッジ５を介して液滴吐出ヘッド６を非移動状態で吸引ユニットに臨ませ、液滴吐出ヘッド６を保全処理することができる。このため、画像認識時に、液滴吐出ヘッド６の各ノズル４６における機能液のメニスカスを適切に維持することができる。
【０１１４】
ところで、第１実施形態および第２実施形態の液滴吐出装置１は、各種の電気光学装置（デバイス）の製造に用いることができる。すなわち、液晶表示装置、有機ＥＬ装置、ＰＤＰ装置および電気泳動表示装置等の製造に適用することができる。もちろん、液晶表示装置等に用いるカラーフィルタの製造にも適用することができる。また、他の電気光学装置としては、金属配線形成、レンズ形成、レジスト形成および光拡散体形成等を包含する装置が考えられる。そして、これらの電気光学装置を備えた電子機器、例えばフラットパネルディスプレイを搭載した携帯電話を提供することができる。
【０１１５】
そこで、この液滴吐出装置１を用いた製造方法を、液晶表示装置の製造方法および有機ＥＬ装置の製造方法を例に、簡単に説明する。
【０１１６】
図１０は、液晶表示装置の断面図である。同図に示すように、液晶表示装置４５０は、上下の偏光板４６２、４６７間に、カラーフィルタ４００と対向基板４６６とを組み合わせ、両者の間に液晶組成物４６５を封入することにより構成されている。また、カラーフィルタ４００および対向基板４６６間には、配向膜４６１、４６４が構成され、対向基板４６６の内側の面には、ＴＦＴ（薄膜トランジスタ）素子（図示せず）と画素電極４６３とがマトリクス状に形成されている。
【０１１７】
カラーフィルタ４００は、マトリクス状に並んだ画素（フィルタエレメント）を備え、画素と画素の境目は、バンク４１３により区切られている。画素の１つ１つには、赤（Ｒ）、緑（Ｇ）、青（Ｂ）のいずれかのフィルタ材料（機能液）が導入されている。すなわち、カラーフィルタ４００は、透光性の基板４１１と、遮光性のバンク４１３とを備えている。バンク４１３が形成されていない（除去された）部分は上記画素を構成し、この画素に導入された各色のフィルタ材料は着色層４２１を構成する。バンク４１３及び着色層４２１の上面には、オーバーコート層４２２及び電極層４２３が形成されている。
【０１１８】
そして、本実施形態の液滴吐出装置１では、バンク４１３で区切られて形成された画素内に、液滴吐出ヘッド６８により、Ｒ・Ｇ・Ｂ各色の機能液を着色層形成領域毎に選択的に吐出している。そして、塗布した機能液を乾燥させることにより、成膜部となる着色層４２１を得るようにしている。また、液滴吐出装置１では、液滴吐出ヘッド６８により、オーバーコート層４２２など各種の成膜部を形成している。もちろん、これら成膜部の描画の際に、上記の液滴吐出装置１のドット位置補正方法を用いて、補正後の吐出パターンデータ（およびΘ軸補正データ）に基づいて描画動作を行っている。
【０１１９】
同様に、図１１を参照して、有機ＥＬ装置とその製造方法を説明する。同図に示すように、有機ＥＬ装置５００は、ガラス基板５０１上に回路素子部５０２が積層され、回路素子部５０２上に主体を為す有機ＥＬ素子５０４が積層されている。また有機ＥＬ素子５０４の上側には、不活性ガスの空間を存して封止用基板５０５が形成されている。
【０１２０】
有機ＥＬ素子５０４には、無機物バンク層５１２ａおよびこれに重ねた有機物バンク層５１２ｂによりバンク５１２が形成され、このバンク５１２により、マトリクス状の画素が画成されている。そして、各画素内には、下側から画素電極５１１、Ｒ・Ｇ・Ｂいずれかの発光層５１０ｂおよび正孔注入／輸送層５１０ａが積層され、且つ全体がＣａやＡｌ等の薄膜を複数層に亘って積層した対向電極５０３で覆われている。
【０１２１】
そして、本実施形態の液滴吐出装置１では、Ｒ・Ｇ・Ｂの各発光層５１０ｂおよび正孔注入／輸送層５１０ａの成膜部を形成するようにしている。また、液滴吐出装置１では、正孔注入／輸送層５１０ａを形成した後に、液滴吐出ヘッド６８に導入する機能液としてＣａやＡｌ等の液体金属材料を用いて、対向電極５０３を形成する等している。もちろん、これら成膜部の描画の際に、上記の液滴吐出装置１のドット位置補正方法を用いて、補正後の吐出パターンデータ（およびΘ軸補正データ）に基づいて描画動作を行っている。
【０１２２】
【発明の効果】
本発明の液滴吐出装置のドット位置補正方法によれば、実際にＸ・Ｙ移動機構および液滴吐出ヘッドを駆動し、アライメントマスクへの描画結果から吐出パターンデータを補正するようにしているため、Ｘ・Ｙ移動機構を含めＸ・Ｙ・Θ移動機構の機械的精度や組立て精度に関らず、液滴吐出ヘッドの描画動作によるワーク上のドット位置を、データ上のドット位置に確実に合致させることができる。
【０１２３】
本発明の液滴吐出方法によれば、上記のドット位置補正方法を用いて実際の描画動作が行われるため、Ｘ・Ｙ移動機構を含めＸ・Ｙ・Θ移動機構の機械的精度等によらず、これに適した描画動作を実行することができ、ワークへの描画精度を極めて向上することができる。
【０１２４】
本発明の電気光学装置およびその製造方法によれば、基板に対する機能液滴の着弾位置が適切に管理された液滴吐出方法を用いての製造であるため、電気光学装置自体を確実に製造することができる。
【図面の簡単な説明】
【図１】本発明の一実施形態に係る液滴吐出装置を模式的に示す平面図である。
【図２】実施形態に係る液滴吐出ヘッドを示す図であり、（ａ）斜視図、（ｂ）模試的平面図である。
【図３】実施形態に係るアライメントマスクを示す平面図である。
【図４】実施形態に係る液滴吐出装置の制御構成を示すブロック図である。
【図５】実施形態に係る液滴吐出装置のドット位置補正方法の処理フローを示すフローチャートである。
【図６】実施形態に係る認識カメラの撮像画面を模試的に示した図である。
【図７】補正データ取得ポイント外における補正データの取得方法を示す説明図である。
【図８】実施形態に係る液滴吐出装置のドット位置補正方法を用いた実際の描画動作の例を示す説明図である。
【図９】第２実施形態に係る液滴吐出装置の平面図である。
【図１０】液晶表示装置の構造を示す断面図である。
【図１１】有機ＥＬ装置の構造を示す断面図である。
【符号の説明】
１　液滴吐出装置
２　Ｘ・Ｙ移動機構（Ｘ・Ｙ・Θ移動機構）
３　Ｘ軸テーブル
４　Ｙ軸テーブル
５　メインキャリッジ（ヘッドキャリッジ）
６　液滴吐出ヘッド
８　認識カメラ
３４　ヘッド角度微調整機構（Ｘ・Ｙ・Θ移動機構）
４５　ノズル列
４６　ノズル
５０　アライメントマスク
５２　フラッシング受け部
５７　規定マーク
５８　基準マーク
１０１　カメラキャリッジ
４５０　液晶表示装置
５００　有機ＥＬ装置
Ｐ　格子点
Ｑ　検査エリア
Ｗ　基板[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a dot position correcting method, an alignment mask, a droplet discharging method, and an electro-optical method for a droplet discharging apparatus that discharges a functional liquid into a dot by a droplet discharging head typified by an inkjet head onto a workpiece such as a substrate. The present invention relates to an apparatus, a method for manufacturing the same, and electronic equipment.
[0002]
[Prior art]
2. Description of the Related Art Conventionally, an ink-jet type droplet discharge apparatus applied to the manufacture of a color filter or the like performs a drawing operation based on discharge pattern data on a substrate and a droplet discharge head by an XY moving mechanism including an X-axis table and a Y-axis table. Is moved with a relatively large stroke in the main scanning direction (X-axis direction) and the sub-scanning direction (Y-axis direction). In this relative movement, the functional liquid is selectively dot-shaped from the nozzle row of the droplet discharge head. (See, for example, Patent Document 1).
In this case, the droplet discharge device measures in advance the deviation of the landing position (dot position) of the functional liquid in the main scanning direction, corrects the discharge timing data based on the measurement result, and adjusts the nozzle characteristic (discharge characteristics). The dot position deviation due to is eliminated.
[0003]
[Patent Document 1]
JP 2001-228321 A (pages 5-6, FIGS. 1 and 15)
[0004]
[Problems to be solved by the invention]
By the way, in this type of droplet discharge device, the dot position on the data and the dot actually discharged on the work are caused by the mechanical accuracy and assembly accuracy of the X / Y moving mechanism or the manufacturing error of the droplet discharge head. The position may deviate.
That is, even if the droplet discharge head and the work are accurately mounted on the XY moving mechanism, the X-axis table (Y-axis table) itself partially has structural distortion (undulation), If the X-axis table is not completely orthogonal to the Y-axis table, the positional relationship between the droplet discharge head and the work fluctuates with the drawing operation. Will occur.
[0005]
The present invention relates to a dot position correction method, an alignment mask, and a droplet discharge method for a droplet discharge device capable of accurately discharging functional droplets to a workpiece, regardless of the mechanical accuracy or the like of the XY moving mechanism. It is an object of the present invention to provide a method, an electro-optical device and a manufacturing method thereof, and an electronic apparatus.
[0006]
[Means for Solving the Problems]
According to the dot position correcting method of the droplet discharge device of the present invention, while moving the droplet discharge head relative to the set work by the XY moving mechanism, the functional liquid is discharged from the nozzle row of the droplet discharge head. Is a dot position correction method for a droplet discharge apparatus that performs a drawing operation of selectively discharging dots in a dot form based on discharge pattern data, wherein a plurality of inspection areas each having a reference mark are arranged in a grid pattern. A mask introducing step of setting a mask in place of a workpiece, a dot drawing step of performing a drawing operation based on alignment ejection pattern data corresponding to a plurality of reference marks, and drawing inspection dots in each inspection area; A recognition step of image-recognizing the position of each inspection dot with respect to the reference mark; Characterized in that and a data correcting step of correcting.
[0007]
According to this configuration, first, a drawing operation based on the alignment ejection pattern data is performed on each of the inspection areas provided in a lattice shape of the set alignment mask to draw the inspection dots. Next, image displacement of the dot position of the inspection dot with respect to the reference mark of each inspection area is recognized by an image, and based on the image recognition result, the dot position is matched with a regular (design target) dot position. To correct the ejection pattern data.
As described above, in the droplet discharge device, the XY moving mechanism and the droplet discharge head are actually driven, and the discharge pattern data is corrected based on the result of drawing on the alignment mask. Thereby, the actual drawing operation using the correction data can perform a drawing operation suitable for the X / Y moving mechanism regardless of the mechanical accuracy or the assembly accuracy, and therefore the dot on the data can be executed. Since the position (target) matches the dot position ejected and landed on the work, it is possible to perform drawing with extremely high dot position accuracy. In addition, since the plurality of inspection areas are formed in a grid pattern on the alignment mask, the dot drawing process can be performed smoothly, and correction data suitable for the drawing operation can be obtained.
[0008]
In this case, the recognition step is performed by moving the recognition camera that performs image recognition by the X / Y moving mechanism and simultaneously capturing each reference mark and each inspection dot within the field of view of the recognition camera. preferable.
[0009]
According to this configuration, the recognition camera can be moved by effectively using the XY moving mechanism, and the inspection dot can be recognized while suitably avoiding the mechanical influence of the XY moving mechanism. .
[0010]
In this case, the XY moving mechanism is configured to be able to move the droplet discharge head and the recognition camera independently of each other, and to perform the maintenance process by moving the droplet discharge head to the non-moving state in parallel with the recognition process. It is preferable to further comprise a maintenance step of performing the following.
[0011]
According to this configuration, since the droplet discharge head and the recognition camera can be moved separately by the XY moving mechanism, the recognition step by the recognition camera can be performed after the completion of the dot drawing step. Head maintenance processing can be performed. Thus, it is possible to prevent the droplet discharge head from being clogged during the recognition step, and to appropriately maintain the meniscus of the functional liquid in the droplet discharge head. The maintenance process is a suction process for sucking the functional liquid of the droplet discharge head, a storage process for storing the droplet discharge head, and the like.
[0012]
In these cases, the Y-axis direction is the main scanning direction of the droplet discharge head, the X-axis direction is the sub-scanning direction of the droplet discharge head, and the discharge pattern data is the discharge timing related to the discharge drive of the droplet discharge head. Data and head movement pattern data relating to the relative movement of the droplet discharge head by the XY movement mechanism, and the data correction step corrects the discharge timing data for the displacement of the dot position in the Y-axis direction, In addition, it is preferable to correct the ejection pattern data by correcting the head movement pattern data for the displacement of the dot position in the X-axis direction.
[0013]
According to this configuration, the deviation of the dot position in the main scanning direction is eliminated by correcting the ejection timing of the droplet discharge head, and the deviation of the dot position in the sub-scanning direction is corrected by sub-scanning the droplet ejection head. This can be solved by making a relatively small movement in the direction. Accordingly, the ejection pattern data can be corrected in a mode suitable for the drawing operation of the droplet ejection head.
[0014]
According to another dot position correcting method of a droplet discharge device of the present invention, a droplet discharge head is moved in a Y-axis direction which is a main scanning direction and a sub-scanning direction by an XY moving mechanism for a set work. Dot position correction of a droplet discharge device that performs a drawing operation of selectively discharging a functional liquid in a dot form from a nozzle row of the droplet discharge head based on discharge pattern data while relatively moving in the X-axis direction. A mask introducing step of setting, instead of a workpiece, an alignment mask in which a plurality of inspection areas each having a reference mark are formed in a grid shape, based on alignment ejection pattern data corresponding to the plurality of reference marks. A test dot group consisting of at least two test dots in each test area using at least two nozzles of a nozzle row. A dot drawing step to form an image, a recognition step of image-recognizing the position of each inspection dot group with respect to each reference mark, and a XY-axis moving mechanism for moving the droplet discharge head to the Θ axis based on the recognition result in the recognition step. A data correction step of generating angle correction data for performing relative rotation correction in the direction and correcting the ejection pattern data in consideration of the angle correction data.
[0015]
According to this configuration, first, a drawing operation based on the alignment ejection pattern data is performed on each of the inspection areas provided in the lattice shape of the alignment mask after the setting to form a group of inspection dots (at least two inspection dots). draw. Next, the displacement of the dot position of the inspection dot group with respect to the reference mark of each inspection area is image-recognized. Next, based on the dot position (displacement data thereof), an angle shift of the droplet discharge head is detected (angle correction data is generated) in order to match a regular dot position, and a shift in the X-axis direction and a Y-axis direction are performed. Is detected, and the ejection pattern data is corrected based on these correction data.
As described above, in the droplet discharge device, the XY, Θ moving mechanism and the droplet discharge head are actually driven, and the discharge pattern data is corrected based on the drawing result on the alignment mask. As a result, in the actual drawing operation using the correction data, regardless of the mechanical accuracy or assembly accuracy of the XY moving mechanism, the dot position (target) on the data and the discharge / landing on the work are performed. Since the dot positions match, it is possible to perform drawing with extremely high dot position accuracy. In addition, since the plurality of inspection areas are formed in a grid pattern on the alignment mask, the dot drawing process can be performed smoothly, and correction data suitable for the drawing operation can be obtained.
[0016]
In this case, it is preferable that at least two nozzles used in the dot drawing process are two nozzles located at the outermost ends in the nozzle row.
[0017]
According to this configuration, at least two inspection dots of the inspection dot group are drawn sufficiently apart from each other, and since these are image-recognized, the displacement of the droplet discharge head in the Θ-axis direction is sufficiently recognized. It is possible to generate appropriate angle correction data.
[0018]
In this case, it is preferable that the length of the inspection area in the X-axis direction and the length of the nozzle row are set to be substantially equal.
[0019]
According to this configuration, a plurality of inspection areas can be efficiently arranged in combination with the fact that two inspection dots are drawn at substantially both end positions of the inspection area.
[0020]
In the case of claim 5, the inspection dot group is composed of three or more inspection dots. In the recognition step, the three or more inspection dots are grouped into a plurality of partial inspection dot groups, and image recognition is performed. In the correction step, it is preferable to generate angle correction data by averaging the recognition results of a plurality of partial inspection dot groups.
[0021]
According to this configuration, when generating the angle correction data, the average value of the recognition results of the plurality of partial inspection dot groups is taken, so that the influence of the ejection characteristics (habit) of the nozzle is preferably avoided. And the accuracy of the angle correction data can be improved.
[0022]
In these cases, the recognition step involves moving the recognition camera that performs image recognition in the X-axis direction and the Y-axis direction by the XY moving mechanism, and within the field of view of the recognition camera, each reference mark and each inspection dot group. It is preferable that this is performed by simultaneously capturing
[0023]
According to this configuration, the recognition camera can be moved by effectively using the XY moving mechanism, and each of the inspection dots can be appropriately avoided by avoiding the mechanical influence of the XY moving mechanism. The group becomes recognizable.
[0024]
In this case, each reference mark may be configured as a plurality of reference mark groups including a plurality of reference marks distributed in the circumferential direction around the drawing position of the inspection dot in the alignment ejection pattern data. ,preferable.
[0025]
According to this configuration, since the reference mark including the plurality of prescribed marks is configured as described above, the image for the inspection dot and the reference mark can be appropriately recognized. In other words, by arranging the specified marks in consideration of the maximum deviation of the dot position due to the peculiarity of the nozzles calculated empirically, it is possible to prevent the inspection dots from being drawn over each specified mark, Image recognition can be performed.
[0026]
In this case, the XY moving mechanism is configured to be able to move the droplet discharge head and the recognition camera independently of each other, and to move the droplet discharge head to a non-moving state in parallel with the recognition process. It is preferable to further include a maintenance process for performing a maintenance process.
[0027]
According to this configuration, since the droplet discharge head and the recognition camera can be moved separately by the XY moving mechanism, after the dot drawing process is completed, the recognition process by the recognition camera can be performed. The droplet discharge head can be maintained. Accordingly, it is possible to prevent the droplet discharge head from being clogged during the recognition step, and to appropriately maintain the meniscus of the functional liquid in the droplet discharge head. The maintenance process is a suction process for sucking the functional liquid of the droplet discharge head, a storage process for storing the droplet discharge head, and the like.
[0028]
In these cases, the ejection pattern data includes ejection timing data relating to ejection driving of the droplet ejection head and head movement pattern data relating to relative movement of the droplet ejection head by the XY movement mechanism. The correction step corrects the ejection timing data for the dot position deviation in the Y-axis direction, and corrects the head movement pattern data for the dot position deviation in the X-axis direction, taking into account the angle correction data. It is preferable to correct the ejection pattern data.
[0029]
According to this configuration, the displacement of the dot position in the main scanning direction is eliminated by correcting the ejection timing of the droplet discharge head, and the displacement of the dot position in the sub-scanning direction is corrected by moving the droplet discharge head in the X-axis direction. This can be solved by relatively moving in the direction. This makes it possible to correct the ejection pattern data in a mode suitable for the drawing operation of the droplet ejection head by the XY movement mechanism.
[0030]
In these cases, it is preferable that at least the surfaces of the plurality of inspection areas of the alignment mask have been subjected to a water-repellent treatment.
[0031]
According to this configuration, the spread of the functional liquid droplet that lands on the alignment mask is suppressed. This makes it easier to identify the position of the center of gravity of the inspection dot, and makes it possible to perform appropriate and accurate image recognition of the dot position. In addition, since the functional droplets after landing can be quickly and appropriately removed, the alignment mask is reused, for example, when re-correcting the ejection pattern data or using it for another droplet ejection device. It is effective in the case.
[0032]
In these cases, the dot drawing step includes a drawing step for inspection in which a drawing operation is performed on each inspection area, and a functional liquid is discharged from all nozzles of the droplet discharge head at a position outside the plurality of inspection areas on the alignment mask. And a flushing step of performing a flushing operation.
[0033]
According to this configuration, it is possible to appropriately eliminate the increase in the viscosity of the functional liquid due to the evaporation of moisture in the nozzle that does not draw the inspection dot. Further, since the flushing operation is directly performed on the alignment mask, the flushing operation can be appropriately performed regardless of the size or the set state of the alignment mask with respect to the XY moving mechanism.
[0034]
In these cases, it is preferable that the droplet ejection head has a plurality of nozzle rows arranged in parallel with each other, and the data correction step is performed by correcting the ejection pattern data for each of the plurality of nozzle rows.
[0035]
According to this configuration, since the ejection pattern data is corrected for each nozzle row, even when the droplet ejection head has a plurality of nozzle rows, the dot position of each nozzle row appropriately matches the designed dot position. Can be done.
[0036]
The alignment mask of the present invention is used for the above-described dot position correcting method of the droplet discharge device of the present invention.
[0037]
According to this configuration, it is possible to provide an alignment mask suitable for correcting the dot position of the droplet discharge device.
[0038]
The droplet discharge method of the present invention uses the above-described dot position correction method of the droplet discharge device of the present invention to correct the corrected discharge pattern data (and angle correction data) for a work set in the droplet discharge device. The drawing operation is performed based on
[0039]
According to this configuration, by utilizing the above-described dot position correction method, the drawing operation corrects the position of the droplet discharge head relative to the work in the X and Y axis directions (Θ axis direction as necessary). Since it is performed while performing, high-precision drawing becomes possible.
[0040]
An electro-optical device according to the present invention includes a film forming section formed on a substrate serving as a work using a functional liquid selectively discharged from a droplet discharge head by using the above-described droplet discharge method according to the present invention. Features.
[0041]
Further, in the method of manufacturing an electro-optical device according to the present invention, a functional droplet is selectively discharged from a droplet discharge head onto a substrate serving as a work by using the above-described droplet discharge method of the present invention to form a film. Forming a portion.
[0042]
According to these configurations, since the production is performed using the droplet discharge method in which the landing positions of the functional droplets on the workpiece are appropriately managed, the electro-optical device itself can be reliably and appropriately produced. In addition, as the electro-optical device (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, examples of the electro-optical device include devices including metal wiring formation, lens formation, resist formation, light diffuser formation, and the like.
[0043]
An electronic apparatus according to the present invention includes the above-described electro-optical device according to the present invention.
[0044]
According to this configuration, it is possible to provide an electronic apparatus equipped with a high-performance electro-optical device. 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.
[0045]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, a droplet discharging device according to an embodiment of the present invention will be described with reference to the accompanying drawings. This droplet discharge device is applied to a so-called flat panel display manufacturing device in an electro-optical device such as an organic EL device, and a filter material or the like is applied from a droplet discharge head to a substrate (work) by an inkjet method. Drawing is performed by selectively discharging functional droplets of a light emitting material or the like in the form of dots to form a desired film-forming portion on a substrate.
[0046]
The dot position correction method of the droplet discharge device of the present embodiment draws an inspection pattern for inspecting a dot position on an alignment mask set in place of a work, and performs image recognition on the pattern for normalization. Is measured from the dot position, and the ejection pattern data for executing the drawing operation is corrected. Therefore, the device configuration of the droplet discharge device will be described first.
[0047]
As shown in FIG. 1, the droplet discharge device 1 includes a gantry (not shown), an XY moving mechanism 2 including an X-axis table 3 and a Y-axis table 4 installed on the gantry, and an X-axis table 3. The main carriage 5 is provided with a head unit 7 on which a droplet discharge head 6 is mounted and a recognition camera 8 for performing image recognition. The substrate W, which is a work, is made of, for example, a glass substrate or a polyimide substrate, and is set on a work table 9 movably attached to the Y-axis table 4. Further, the droplet discharge device 1 incorporates a controller 10 (control means, see FIG. 4) which controls the XY moving mechanism 2, the droplet discharge head 6, the recognition camera 8 and the like.
[0048]
The XY moving mechanism 2 is a so-called XY robot, and the X-axis table 3 is located above the Y-axis table 4. The X-axis table 3 includes an X-axis slider 21 on which the main carriage 5 is movably mounted in the X-axis direction, a pulse-driven X-axis linear motor 22 incorporated between the X-axis slider 21 and the main carriage 5, And an X-axis linear scale 23 attached to the axis slider 21.
[0049]
The X-axis linear scale 23 has slits at regular intervals in parallel with the X-axis direction, and an X-axis linear sensor 24 is provided on the main carriage 5 corresponding to the X-axis linear scale 23 (FIG. 4). reference). In other words, the X-axis linear scale 23 and the X-axis linear sensor 24 form an X-axis linear encoder. The X-axis linear encoder sets the position of the main carriage 5 (the position of the droplet discharge head 6 and the recognition camera 8) to 0. It is configured to be readable with an accuracy of 1 μm.
[0050]
The Y-axis table 4 includes a Y-axis slider 26 on which the work table 9 is movably mounted in the Y-axis direction, a pulse-driven Y-axis linear motor 27 incorporated between the Y-axis slider 26 and the work table 9, And a Y-axis linear scale 28 attached to the axis slider 26. The work table 9 incorporates a rotation mechanism for rotating the work table 9 in-plane in the θ-axis direction and a suction mechanism for suction mounting the substrate W (both are not shown).
[0051]
The Y-axis linear scale 28 has slits at regular intervals in parallel with the Y-axis direction, and a Y-axis linear sensor 29 is provided on the work table 9 corresponding to the Y-axis linear scale 28 (FIG. 4). reference). That is, a Y-axis linear encoder is constituted by the Y-axis linear scale 28 and the Y-axis linear sensor 29. The Y-axis linear encoder can adjust the position of the work table 9 (the position of the substrate W or the alignment mask 50) to an accuracy of 0.1 μm. It is configured to be readable.
[0052]
The X / Y moving mechanism 2 configured as described above drives the droplet discharge head 6 to discharge in accordance with the moving position information of the main carriage 5 and the moving position information of the work table 9, and moves the droplet discharging head 6 to a predetermined position on the substrate W. Drawing is performed by discharging the liquid.
[0053]
Specifically, the droplet discharge device 1 has a configuration in which the droplet discharge head 6 is driven to discharge in synchronization with the movement of the substrate W by the Y-axis table 4. The reciprocating operation of the substrate W in the Y-axis direction by the axis table 4 is performed. Corresponding to this, the so-called sub-scanning is performed by a forward movement of the X-axis table 3 as a pitch feed operation of the droplet discharge head 6 in the X-axis direction. The drawing operation in the scanning is performed based on the ejection pattern data stored in the controller 10.
[0054]
In the present embodiment, the substrate W is moved in the main scanning direction with respect to the droplet discharge head 6, but the configuration may be such that the droplet discharge head 6 is moved in the main scanning direction. Alternatively, the substrate W may be fixed, and the droplet discharge head 6 may be moved in the main scanning direction and the sub-scanning direction. Conversely, a configuration may be adopted in which the droplet discharge head 6 is fixed and the substrate W is moved in the main scanning direction and the sub-scanning direction. Of course, contrary to the present embodiment, the X-axis direction may be the main scanning direction, and the Y-axis direction may be the sub-scanning direction.
[0055]
Although the details will be described later, this drawing operation, which is the actual droplet discharge operation, is performed based on the corrected discharge pattern data corrected based on the drawing result on the alignment mask 50 set on the work table 9 instead of the substrate W. It is done based on. At this time, if necessary, the droplet discharge head 6 is rotated in-plane with respect to the substrate W by a head angle fine adjustment mechanism 34 described later, thereby realizing drawing with high dot position accuracy.
[0056]
The head unit 7 has a sub-carriage (not shown) on which the droplet discharge head 6 is mounted, and a table 32 (see FIG. 4) for rotating the sub-carriage in-plane in the axial direction. The table 32 is powered by a motor 33 that can rotate forward and backward. When the motor 33 rotates forward and backward, the table 32 and the sub-carriage rotate the droplet discharge head 6 in the XY plane. Let it. That is, the Θtable 32 and the Θmotor 33 constitute a head angle fine adjustment mechanism 34 for rotating the droplet discharge head 6 relative to the substrate W by an angle.
[0057]
As shown in FIG. 2, the droplet discharge head 6 is of a so-called two-unit type. The head body 41 includes a nozzle forming plate 43 having a nozzle surface 42 and a rectangular parallelepiped pump unit connected to the nozzle forming plate 43. 44. This type of ink jet type droplet discharge head 6 is configured by using a piezoelectric element (piezo element) as an energy generating element for driving ejection, or using an electrothermal converter.
[0058]
In the droplet discharge head 6, the head body 41 protrudes from the lower surface of the sub-carriage, and two nozzle rows 45 are formed in parallel with each other on the lower surface of the head body 41, that is, the nozzle surface. Each nozzle row 45 extends in the sub-scanning direction (X-axis direction), and 180 nozzles 46 (shown schematically in the drawing) are arranged at an equal pitch (1/180 inch). Have been. A total of 360 nozzles 46 are arranged in a zigzag pattern as a whole, the overall nozzle pitch in the sub-scanning direction is set to be as small as 1/360 inch, and the distance between nozzles in the main scanning direction (the distance between nozzle rows 45). ) Is set to 1/10 inch.
[0059]
The droplet discharge head 6 is supplied with a functional liquid from a functional liquid supply mechanism (not shown), and discharges the functional liquid in dots from each nozzle 46. In the following description, the two outermost nozzles 46 of the nozzle row 45 are referred to as nozzles 1 and 180, and the entire nozzle row 45 is divided into odd-numbered nozzles and even-numbered nozzles. “+” Shown in the droplet discharge head 6 in FIG. 1 indicates the rotation center of the droplet discharge head 6 by the head angle fine adjustment mechanism 34, and in this case, matches the center position of the droplet discharge head 6. ing.
[0060]
As shown in FIG. 3, the alignment mask 50 is formed, for example, of glass or the like in a rectangular and thick shape. The alignment mask 50 is used to correct the dot position of the droplet discharge head 6 in the droplet discharge device 1, and is provided on the work table 9 of the droplet discharge device 1 prior to the main drawing operation on the substrate W. Set. The dot position refers to the position (landing position) of a dot that is formed by a functional liquid droplet that is discharged from the liquid droplet discharging head 6 and landed on the surface of the alignment mask 50 (substrate W).
[0061]
On the surface of the alignment mask 50, a plurality of inspection areas Q formed in a square lattice shape for inspecting dot positions, and a pair of front and rear alignment marks 51 positioned outside the plurality of inspection areas Q outside in the Y-axis direction. And a flushing receiving portion 52 that is located further on the front side or front and rear of the front alignment mark 51. The surface of the alignment mask 50 is subjected to a water-repellent treatment. Therefore, the spread of the functional droplet (dot) landing on the alignment mask 50 is suppressed, and the dot position can be appropriately recognized by the recognition camera 8 as an image.
[0062]
The plurality of inspection areas Q are provided so as to be located at respective grid points (each grid point is represented by POO and representatively represented by P) at 30 mm intervals in the square lattice. In each inspection area Q, as shown in the enlarged view of FIG. 3B, three reference mark rows 56 that indicate regular (designed) dot positions are formed in parallel with each other.
[0063]
Each reference mark row 56 extends in the X-axis direction starting from each lattice point P side, and is configured by arranging 90 square defined marks 57 at an equal pitch (1/90 inch). Each of the prescribed marks 57 is formed in a size of 50 μm × 50 μm by laser etching or the like, but is not limited to such a rectangular geometric shape and size. A total of 270 prescribed marks 57 are arranged in a zigzag pattern as a whole, the overall mark pitch in the X-axis direction is set to 1/180 inch, and the mark-to-mark distance in the Y-axis direction (between the reference mark rows 56). Distance) is set to 1/180 inch.
[0064]
In each inspection area Q, a plurality of sets of reference marks 58 each including a set of four prescribed marks 57 forming each of the vertices of the square are formed. The plurality of sets of reference marks 58 constitute a reference mark group as a whole. Make up. In other words, each reference mark 58 defines a regular dot position at the center (centroid of the square) and a position that is 1/180 inch away from the regular dot position in the front, rear, left and right directions (X-axis direction and Y-axis direction). A mark 57 is formed.
[0065]
In other words, the reference mark 58 is configured by dispersing four reference marks 57 at equal intervals around the drawing position (regular dot position) of the inspection dot in the alignment ejection pattern data in the circumferential direction. . Then, as will be described in detail later, image recognition is performed by simultaneously capturing inspection dots drawn at the regular dot positions based on the ejection pattern data for alignment together with the reference marks 58 in the field of view of the recognition camera 8. The position of the inspection dot (displacement from the regular dot position) is detected.
[0066]
The pair of alignment marks 51 are drawn in a cross shape by laser etching or the like, and serve as a reference for positioning when setting the alignment mask 50 on the work table 9 on the premise of image recognition. That is, the alignment mask 50 is positioned on the work table 9 in the X-axis direction and the Θ-axis direction after the recognition camera 8 performs image recognition of the pair of alignment marks 51.
[0067]
The flushing receiving portion 52 extends in parallel with the X-axis direction beyond the plurality of inspection areas Q arranged in the X-axis direction, and is configured as a flat flushing area. The flushing receiving section 52 receives the flushing of the droplet discharge head 6 (discharge discharge of the functional liquid from all the nozzles 46) facing directly above this position, and holds the functional liquid without scattering. Thus, the flushing operation of the droplet discharge head 6 can be directly performed on the alignment mask 50.
[0068]
Although not shown, the actual droplet discharge device 1 has a configuration in which the flushing receiving portion 52 is omitted because the flushing box for receiving flushing is mounted on the Y-axis table 4 at positions before and after the work table 9. You can also. However, if the flushing receiving portion 52 is provided in advance in the alignment mask 50 as in the present embodiment, the size of the alignment mask 50 becomes larger than the work table 9 and each flushing box is closed. Also, the flushing area in the droplet discharge device 1 can be appropriately secured. This means that the alignment mask having the specified size can be used, so that the original accuracy of the alignment mask can be maintained and the cost can be reduced.
[0069]
The recognition camera 8 (CCD camera) is fixedly mounted on the main carriage 5 adjacent to the droplet discharge head 6, as shown in FIG. The recognition camera 8 captures the inspection dot and the reference mark 58 in the field of view, captures the image, and recognizes the image. The recognition camera 8 calculates the relative position (displacement) of the inspection dot with respect to the reference mark 58, ie, the normal dot position, by using a coordinate value. Recognize as
[0070]
In this case, the recognition camera 8 is configured to simultaneously capture the plurality of reference marks 58 and the plurality of inspection dots in the field of view, and to collectively recognize the positions of the plurality of inspection dots. The recognition camera 8 also performs image recognition of the pair of alignment marks 51.
[0071]
When the droplet discharge device 1 is viewed from the control system, as shown in FIG. 4, the control system of the droplet discharge device 1 basically includes design position data and droplet discharge of the main carriage 5 and the work table 9. An input unit 72 having an operation panel 71 for inputting image data and the like by operation in addition to position data on the design of dots by the head 6, and a display unit 74 having a display 73 for displaying a screen shot by the recognition camera 8. A position detection unit 75 having a recognition camera 8 for performing position recognition such as a dot position, and a feed having an X-axis linear sensor 24 and a Y-axis linear sensor 29 for detecting the positions of the main carriage 5 and the work table 9. A drive unit 77 having a detection unit 76, a droplet discharge head 6, an XY moving mechanism 2, a head angle fine adjustment mechanism 34, and various drivers for driving a display 73. , And a control unit 78 for overall control of the included liquid droplet ejection apparatus 1 of each section (controller 10), the.
[0072]
The drive unit 77 includes a head driver 81, a display driver 82, and a motor driver 83. The head driver 81 controls the ejection drive of the droplet ejection head 6 according to the instruction of the control unit 78, and the display driver 82 controls the display 73 according to the instruction of the control unit 78. The motor driver 83 includes an X-axis motor driver 83a, a Y-axis motor driver 83b, and a Θ-axis motor driver 83c. , 27 and the Θ motor 33 of the head angle fine adjustment mechanism 34 are driven.
[0073]
The control unit 78 includes a CPU 91, a ROM 92, a RAM 93, and a P-CON 94, which are connected to each other via a bus 95. The ROM 92 has a control program area for storing control programs and control data processed by the CPU 91 and a control data area for storing control data and the like for performing image recognition and drawing.
[0074]
The RAM 93 stores, in addition to various register groups, an input position data area for storing position data such as a design (regular) dot position input from the outside, and a dot for storing dot position data obtained from the alignment mask 50 by the recognition camera 8. To correct a position data area and an alignment mark position data area for storing position data of the alignment mark 51, an image data area for temporarily storing image data, a drawing data area for storing drawing data for drawing, and a dot position correction And the like are used as various work areas for control processing.
[0075]
In the P-CON 94, a logic circuit for complementing the function of the CPU 91 and for handling interface signals with peripheral circuits, which is constituted by a gate array, a custom LSI, or the like, is incorporated. Therefore, the P-CON 94 receives various commands and image data from the input unit 72 as they are or processes them and takes them into the bus 95, and in conjunction with the CPU 91, data and control output from the CPU 91 and the like to the bus 95. The signal is output to the drive unit 77 as it is or after processing.
[0076]
The CPU 91 inputs various detection signals, various commands, various data, and the like via the P-CON 94 according to the control program in the ROM 92, and processes various data (ejection pattern data) in the RAM 93 according to the above configuration. After that, various control signals are output to the drive unit 77 via the P-CON 94 to control the entire droplet discharge device 1.
[0077]
For example, the dot position data obtained by the recognition camera 8 from the alignment mask 50 is stored in the RAM 93 and compared with regular dot position data according to a control program in the ROM 92. Then, based on the comparison result, correction data for executing the drawing operation so as to eliminate the deviation of the dot position is generated. The correction data includes: Θ-axis correction data (angle correction data) for rotating the droplet discharge head 6 in-plane with respect to the substrate W during the drawing operation to perform 補正 -axis position correction (rotation correction); And X-axis correction data and Y-axis correction data for position correction in the Y-axis direction.
[0078]
The droplet ejection head 6, the X / Y moving mechanism 2, the head angle fine adjustment mechanism 34, and the like are controlled based on the correction data and the ejection pattern data related to the X, Y, and Θ axes to obtain a predetermined ejection timing condition. The main drawing operation of the droplet discharge device 1 is performed, for example, drawing is performed on the substrate W under predetermined head moving conditions.
[0079]
It should be noted that a host such as a personal computer may be used in place of the control configuration of the droplet discharge device 1 described above, and a control program may be stored in a hard disk of the host, so as to function integrally with the droplet discharge device 1. Needless to say, a simple control configuration may be used.
[0080]
Here, the dot position correction method of the droplet discharge device 1 will be described step by step. FIG. 5 shows a series of steps of the dot position correction method. As shown in FIG. 5, first, an alignment mask 50 is set on the work table 9 instead of the substrate W (step S1), and the recognition camera 8 is used. This is positioned on the work table 9 (step 2).
[0081]
Next, a drawing operation based on the alignment ejection pattern data is performed to draw a plurality of test dots in each test area Q of the alignment mask 50 (Step 3). Then, using the recognition camera 8, the inspection dots and the reference marks 58 are image-recognized to generate dot position correction data (step 4), and the ejection pattern data is corrected based on the correction data. (Step 5). Hereinafter, each step will be described in detail with reference to FIGS.
[0082]
In the recognition operation of the recognition camera 8 in step S2, first, the X-axis table 3 and the Y-axis table 4 of the XY moving mechanism 2 are driven to move the recognition camera 8, and one of the alignment marks 51 is moved to the recognition camera 8. Capture within the field of view. When one of the alignment marks 51 is recognized by the recognition camera 8, the Y-axis table 4 is driven to move the recognition camera 8 in the Y-axis direction, and the other alignment mark 51 is captured in the field of view of the recognition camera 8. Recognize this.
[0083]
Then, based on the recognition result of the pair of alignment marks 51 by the recognition camera 8, the rotation mechanism of the work table 9 is driven so that the positions of the two alignment marks 51 in the X-axis direction are the same. Thereby, the reference mark row 56 on the alignment mask 50 extends parallel to the X-axis direction, that is, orthogonal to the Y-axis direction, and the alignment mask 50 is positioned by the XY moving mechanism 2. After the positioning, the above-described recognition operation is performed again for confirmation, and the recognition operation in step S2 is completed.
[0084]
The ejection pattern data for alignment in step S3 is stored in the ROM 92, and this data is used to draw inspection dots at regular dot positions (targets) defined by the reference marks 58 of each inspection area Q. . In this case, the ejection drive of the droplet ejection head 6 is performed using one nozzle row 45 of the two nozzle rows 45 and is performed using odd-numbered nozzles of the nozzle row 45.
[0085]
That is, since the nozzles 46 of the droplet discharge head 6 and the defining marks 57 of the respective reference marks 58 are arranged as described above (see FIGS. 2 and 3), the droplet discharge head 6 has one side. Only a total of 90 odd-numbered nozzles in the nozzle row 45 are selectively driven for ejection. As a result, the inspection dot to be drawn does not overlap with the specified mark 57 (see FIG. 6), and in each inspection area Q, an inspection dot group including 90 inspection dots is position-recognized. It will be rendered as possible.
[0086]
In the drawing operation in step S3, first, the Y-axis table 4 is driven to move the alignment mask 50 forward in the main scanning direction (to move to the near side in the Y-axis direction), and to check each inspection area Q located on this movement path. In response, the droplet discharge head 6 is selectively driven to discharge. In this case, the discharge of the functional liquid by the first nozzle of the nozzle row 45 is performed with each grid point P in the main scanning as a target. That is, the inspection dot by the first nozzle is drawn in the order of the lattice point P00, the lattice point P01, and the lattice point P02. Then, when the position exceeds the foremost inspection area Q in the main scanning, the flushing operation of the droplet discharge head 6 is performed at the position of the flushing receiving portion 52 or the flushing box.
[0087]
When one main scan is completed, subsequently, the Y-axis table 4 is driven to move the alignment mask 50 in the main scanning direction, and then the X-axis table 3 is driven, and the main carriage 5 is moved by one pitch. Is moved in the sub-scanning direction by an amount corresponding to one inspection area Q (moved to the position of the lattice point P10). Then, in synchronization with the forward movement of the alignment mask 50 in the main scanning direction again, the selective ejection drive of the droplet ejection head 6 and the flushing operation are performed. By repeating this several times, inspection dot groups are drawn on the entire inspection area Q of the alignment mask 50.
[0088]
The drawing operation based on the ejection pattern data for alignment is performed by the same data development as the main drawing operation based on the ejection pattern data to be drawn on the substrate W. A method is also conceivable in which, after moving to the position, the nozzle 46 is selectively driven to discharge while the droplet discharge head 6 is in a standby state. According to this method, it is possible to avoid a bug in data development and a drawback in drawing control using ejection timing data.
[0089]
FIGS. 6A and 6B schematically show the imaging screen of the recognition camera 8, in which two locations at the outermost end in the inspection area Q each having the lattice point P00 are captured. is there. In the recognition operation of the recognition camera 8 in step S4, the displacement of the dot position in the Θ-axis direction (the inclination of the nozzle row 45) is obtained by recognizing the two outermost ends in one inspection area Q. Is taken into account, the displacement of the dot position in the X-axis direction and the Y-axis direction is obtained.
[0090]
Specifically, first, the X-axis table 3 and the Y-axis table 4 of the XY moving mechanism 2 are driven to relatively move the recognition camera 8 to move to the inspection area Q having the lattice point P00, A plurality of inspection dots located at the outermost end of the image and a plurality of reference marks 58 corresponding to the inspection dots are simultaneously captured in the field of view of the recognition camera 8 to perform image recognition (see FIG. 3A). . In the image recognition, after the position of the center of gravity of the substantially circular inspection dot is obtained, the displacement of the center of gravity of the inspection dot with respect to the normal dot position defined by the reference mark 58 is obtained as relative coordinate values (ΔX, ΔY). (See FIG. 3 (c)).
[0091]
In this case, the displacements of a plurality of inspection dots captured by the recognition camera 8 at the same time are respectively obtained, and the average values thereof are taken to obtain the displacements of the dot positions in the X-axis direction and the Y-axis direction on the lattice point P00 side of the inspection area Q. And This makes it possible to actually recognize two (preferably the outermost two) dot positions in the image, but as described above, the partial inspection dot group including a plurality of inspection dots Are taken as a set and the average value is taken, so that the influence of the ejection characteristics of the nozzle 46 can be suitably avoided.
[0092]
When the image recognition on the lattice point P00 side is completed, the X-axis table 3 is driven to move the recognition camera 8 on the same inspection area Q in the X-axis direction, and to move the recognition camera 8 to the other outer end of the inspection area Q. A plurality of inspection dots to be inspected and a plurality of reference marks 58 corresponding to the inspection dots are simultaneously captured in the field of view of the recognition camera 8 and image recognition is performed (see FIG. 3B). Also in this case, the average value of the displacements of the plurality of inspection dots in the partial inspection dot group is calculated to determine the displacement of the dot position in the X-axis direction and the Y-axis direction.
[0093]
Then, based on two displacement data in the X and Y axes directions obtained from one inspection area Q, Θ-axis correction data is generated in consideration of the rotation center of the droplet discharge head 6, and Θ-axis correction data is generated. The X-axis correction data and the Y-axis correction data with consideration are generated. That is, a plurality of (3 or more) inspection dots in the inspection area Q are divided into two sets of partial inspection dot groups, and the recognition results of the respective partial inspection dot groups are averaged to obtain Θ-axis correction data. Are generated, and X-axis correction data and Y-axis correction data are generated. Then, the correction data relating to the X, Y, and Θ axes is stored in the RAM 93 as correction data at (the coordinates of) the lattice point P00.
[0094]
Needless to say, depending on the inspection area Q, the 言 う -axis correction data may be generated as 0 (no need for correction), or the X-axis correction data and the Y-axis correction data may be generated as 0. . In addition, the dot groups are divided into two sets of partial inspection dots, but not limited to the two sets at the outermost end, but may be two sets at an arbitrary position. Alternatively, the inspection dots may be shared among a plurality of groups of partial inspection dots.
[0095]
After the correction data of the lattice point P00 is generated, the XY moving mechanism 2 is driven again to perform image recognition of the inspection area Q having the lattice point P01 in the same manner, and the correction data of the lattice point P01 is generated. You. Then, when all the image recognition of the plurality of inspection areas Q in the main scanning direction is completed and the correction data of each grid point P is generated, the X-axis table 3 is driven to drive the main carriage 5 by one pitch, that is, The data is moved in the sub-scanning direction by one inspection area Q, and after the image recognition, the correction data of the lattice point P10 is generated. Thereafter, the same image recognition operation is repeated to perform image recognition of the entire inspection area Q of the alignment mask 50, and correction data is generated for each of all the grid points P (data is obtained in a grid). .
[0096]
By setting the area length (slightly less than 30 mm) of the inspection area Q in the X-axis direction to be almost equal to the length (1 inch) of the nozzle row 45, two inspection dots by the first nozzle and the 179 nozzle are: It is drawn at substantially both end positions of the inspection area Q. With such a configuration, correction data is efficiently acquired by reducing the number of inspection areas Q as much as possible. In the present embodiment, correction data other than the lattice point P is generated as follows.
[0097]
For example, as shown in FIG. 7, when focusing on the dot position of the first nozzle, the correction data of the point Pa is proportional to the correction data of the four grid points (P00, P01, P10, P11) around this point. Generated by allocation. That is, the X-axis correction data of the point Pa is
(Equation 1)

Is required. Note that x + y = u + v = 30 (mm). Similarly, the Y-axis correction data and the Θ-axis correction data of the point Pa are obtained.
[0098]
The correction of the ejection pattern data in step S5 includes the plurality of X-axis correction data and the plurality of Y-axis correction data (all of which include correction data other than the grid point P) among the plurality of X-, Y-, and Θ-axis correction data. ) Is performed for each nozzle row 45. Specifically, the ejection pattern data includes ejection timing data relating to the ejection drive of the droplet ejection head 6 and head movement pattern data relating to the relative movement of the droplet ejection head 6 with respect to the substrate W by the XY moving mechanism 2. The head movement pattern data is corrected based on a plurality of X-axis correction data, and the ejection timing data is corrected based on a plurality of Y-axis correction data.
[0099]
As a result, the displacement of the dot position in the X-axis direction (sub-scanning direction) is eliminated by the fine movement of the main scanning droplet discharge head 6 (main carriage 5) in the X-axis direction. On the other hand, the displacement of the dot position in the Y-axis direction (main scanning direction) is eliminated by shifting the ejection timing of the droplet ejection head 6.
[0100]
In this case, the correction for shifting the ejection timing is performed by changing the position (address) where the drawing data is developed. As described above, since the Y-axis linear encoder can read with an accuracy of 0.1 μm, drawing data can be developed in units of 0.1 μm in the Y-axis direction. For example, the address of the Y coordinate 0 mm is “00000”, It is assumed that the address of the Y coordinate 1 mm is “10000” and the address of the Y coordinate 10 mm is “100,000”. In this case, when the Y-axis correction data is “−1 μm” at the point of the Y coordinate of 10 mm, that is, when the dot is drawn 1 μm before the Y coordinate of 10 mm, the address for developing the drawing data at this point is “100001”. ", The ejection timing data is corrected.
[0101]
After the ejection pattern data is corrected in a manner suitable for the drawing operation of the droplet discharge head 6 in this manner, the main drawing on the substrate W is performed based on the corrected ejection pattern data and the Θ-axis correction data. The operation will be performed.
[0102]
Here, a simple example of the main drawing operation will be described with reference to FIG. The coordinates of the grid point P00 shown in FIG. 3 are (X, Y) = (0, 0) mm, the coordinates of the grid point P01 are (0, 30) mm, and the coordinates of the grid point P02 are (0, 60) mm. The correction data of each of the lattice points P00, P01, and P02 is as shown in FIG. In this case, the above equation (1) becomes
(Equation 2)

And can be transformed.
[0103]
Therefore, for example, if the main drawing operation is performed while performing the correction in units of 10 mm in the Y-axis direction, the Y coordinate of 10 mm and the Y coordinate of 20 mm are obtained from the relationship between “u” and “v” shown in Expression (2). At this point, the droplet discharge head 6 is slightly moved in the X-axis direction so that the value of 1/3 of the difference between the X-axis correction data of the lattice point P00 and the X-axis correction data of the lattice point P01 is corrected. .
[0104]
Similarly, at each point of the Y coordinate between the two grid points P, the value of the difference of the Y-axis correction data of the two grid points P is corrected so that the value of の of the difference is 1/3. The ejection timing is changed, and the head angle fine adjustment mechanism 34 adjusts the Θ of the droplet ejection head 6 so that the value of 差 of the difference between the Θ axis correction data of the two lattice points P is corrected. A minute rotation in the axial direction is performed. In addition, “α” shown in FIG. 3C is shown in consideration of the movement of the first nozzle in the X-axis direction due to the rotation of the droplet discharge head 6.
[0105]
As described above, in the droplet discharge device 1, the XY moving mechanism 2 and the droplet discharge head 6 are actually driven to correct the discharge pattern data from the drawing result on the alignment mask 50, and the corrected discharge is performed. An actual drawing operation on the substrate W is performed based on the pattern data and the Θ-axis correction data. Accordingly, even if there is a structural distortion or the like in the X / Y moving mechanism 2, the drawing operation is performed to appropriately eliminate the structural distortion, so that the drawing with high dot position accuracy can be realized.
[0106]
The XY moving mechanism described in the claims is constituted by the head angle fine adjusting mechanism 34 and the XY moving mechanism 2, but instead of the head angle fine adjusting mechanism 34, a substrate W (work) is used. A work rotating mechanism for rotating in the axial direction may be provided, and the XY moving mechanism may be configured by the work rotating mechanism and the XY moving mechanism 2. In this case, the rotation mechanism of the work table 9 is a main part of the work rotation mechanism.
[0107]
Further, the number of nozzles 46, the number of nozzle rows 45, and the extending direction of the nozzle rows 45 of the above-described droplet discharge head 6 are also arbitrary. For example, the droplet discharge head 6 is tilted at a predetermined angle with respect to the main scanning direction. It may be something. Of course, the number of the droplet discharge heads 6 is not limited to one, and when there are a plurality of the droplet discharge heads, the arrangement pattern may be arbitrary such as a staggered arrangement or a stepwise arrangement. It is preferable that all the ejection nozzles 46 are continuous in the sub-scanning direction. Further, the correction of the ejection pattern data may be individually performed for a plurality of droplet ejection heads 6, and the correction in the Θ-axis direction at that time is performed for all the droplet ejection heads 6 collectively. It is preferable to do so.
[0108]
Further, when the initial accuracy is deviated due to aging of the XY moving mechanism 2, it is preferable to review the correction data. In this case, the alignment mask 50 used initially may be re-introduced into the droplet discharge device 1.
[0109]
Needless to say, even if the head angle fine adjustment mechanism 34 is not provided, it is possible to sufficiently correct the dot position even by two-dimensional correction in the X and Y axis directions. In this case, in the drawing operation of step 3 shown in FIG. 5, one inspection dot is drawn in one inspection area Q, and in the image recognition of step 4, the dot position recognized in one inspection area Q is sufficient. Is enough. Then, based on the plurality of X-axis correction data and the plurality of Y-axis correction data, the ejection pattern data may be corrected in the same manner as described above.
[0110]
The work to be discharged by the droplet discharge device 1 may be a general recording medium such as a cut sheet or a printing tape, in addition to the glass substrate as described above.
[0111]
Next, a second embodiment will be described with reference to FIG. In the droplet discharge device 1 of the present embodiment, the droplet discharge head 6 is mounted on the main carriage 5 (head carriage), the recognition camera 8 is mounted on the camera carriage 101, and the droplet discharge head 6 and the recognition camera 8 , Each independently movable in the X-axis direction.
[0112]
An X-axis sensor 102 is provided facing the movement path of the carriages 5 and 101. The X-axis sensor 102 controls the relative position of the main carriage 5 and the camera carriage 101, that is, the relative position of the droplet discharge head 6 and the recognition camera 8. It is possible to directly detect the physical positional relationship. Further, although not shown, the nozzle surface 42 of the droplet discharge head 6 (the four peripheral edges thereof) is received at the home position in the X-axis direction, and maintenance processing such as suction and storage of the functional liquid of the droplet discharge head 6 is performed. Is provided.
[0113]
According to the present embodiment, during the image recognition operation of the recognition camera 8 via the camera carriage 102, the droplet discharge head 6 faces the suction unit via the main carriage 5 in a non-moving state. Can be maintained. Therefore, at the time of image recognition, the meniscus of the functional liquid in each nozzle 46 of the droplet discharge head 6 can be appropriately maintained.
[0114]
By the way, the droplet discharge devices 1 of the first embodiment and the second embodiment can be used for manufacturing various electro-optical devices (devices). That is, the present invention can be applied to manufacturing of a liquid crystal display device, an organic EL device, a PDP device, an electrophoretic display device, and the like. Of course, the present invention can be applied to the manufacture of a color filter used for a liquid crystal display device or the like. Further, as other electro-optical devices, devices including metal wiring formation, lens formation, resist formation, light diffuser formation, and the like can be considered. In addition, it is possible to provide an electronic device equipped with these electro-optical devices, for example, a mobile phone equipped with a flat panel display.
[0115]
Therefore, a manufacturing method using the droplet discharge device 1 will be briefly described by taking a method of manufacturing a liquid crystal display device and a method of manufacturing an organic EL device as examples.
[0116]
FIG. 10 is a cross-sectional view of the liquid crystal display device. As shown in the figure, a liquid crystal display device 450 is configured by combining a color filter 400 and a counter substrate 466 between upper and lower polarizing plates 462 and 467, and sealing a liquid crystal composition 465 between the two. I have. Further, alignment films 461 and 464 are formed between the color filter 400 and the counter substrate 466, and a TFT (thin film transistor) element (not shown) and a pixel electrode 463 are formed in a matrix on the inner surface of the counter substrate 466. Is formed.
[0117]
The color filter 400 includes pixels (filter elements) arranged in a matrix, and boundaries between pixels are separated by banks 413. Any one of red (R), green (G), and blue (B) filter materials (functional liquid) is introduced into each of the pixels. That is, the color filter 400 includes a light-transmitting substrate 411 and a light-shielding bank 413. The portion where the bank 413 is not formed (removed) constitutes the pixel, and the filter material of each color introduced into this pixel constitutes the colored layer 421. Overcoat layers 422 and electrode layers 423 are formed on the upper surfaces of the banks 413 and the coloring layers 421.
[0118]
In the droplet discharge device 1 of the present embodiment, the R, G, and B functional liquids are selected by the droplet discharge head 68 for each of the coloring layer forming regions in the pixels formed by the banks 413. Is ejected. Then, by drying the applied functional liquid, a colored layer 421 to be a film forming unit is obtained. In the droplet discharge device 1, various film formation units such as the overcoat layer 422 are formed by the droplet discharge head 68. Of course, at the time of drawing in these film forming units, the drawing operation is performed based on the corrected discharge pattern data (and the Θ-axis correction data) by using the dot position correcting method of the droplet discharge device 1 described above. .
[0119]
Similarly, an organic EL device and a method of manufacturing the same will be described with reference to FIG. As shown in the figure, in the organic EL device 500, a circuit element portion 502 is laminated on a glass substrate 501, and an organic EL element 504, which is a main component, is laminated on the circuit element portion 502. A sealing substrate 505 is formed above the organic EL element 504 with a space for an inert gas.
[0120]
In the organic EL element 504, a bank 512 is formed by an inorganic bank layer 512a and an organic bank layer 512b superposed on the inorganic bank layer 512a, and the banks 512 define pixels in a matrix. In each pixel, a pixel electrode 511, a light-emitting layer 510b of any one of R, G, and B and a hole injection / transport layer 510a are stacked from below, and a plurality of thin films of Ca, Al, or the like are entirely formed. Are covered with a counter electrode 503 that is laminated over the entire surface.
[0121]
Then, in the droplet discharge device 1 of the present embodiment, the film forming portions of the R, G, and B light emitting layers 510b and the hole injection / transport layers 510a are formed. In the droplet discharge device 1, after forming the hole injection / transport layer 510a, the counter electrode 503 is formed using a liquid metal material such as Ca or Al as a functional liquid to be introduced into the droplet discharge head 68. Are equal. Of course, at the time of drawing in these film forming units, the drawing operation is performed based on the corrected discharge pattern data (and the Θ-axis correction data) by using the dot position correcting method of the droplet discharge device 1 described above. .
[0122]
【The invention's effect】
According to the dot position correction method of the droplet discharge device of the present invention, the XY moving mechanism and the droplet discharge head are actually driven to correct the discharge pattern data from the result of drawing on the alignment mask. Regardless of the mechanical accuracy or assembly accuracy of the XY moving mechanism including the XY moving mechanism, the dot position on the work by the drawing operation of the droplet discharge head is surely set to the dot position on the data. Can be matched.
[0123]
According to the droplet discharge method of the present invention, since the actual drawing operation is performed using the above-described dot position correction method, the actual accuracy of the XY moving mechanism including the XY moving mechanism depends on the mechanical accuracy and the like. Therefore, a drawing operation suitable for this can be performed, and the drawing accuracy on the work can be extremely improved.
[0124]
According to the electro-optical device and the method for manufacturing the same of the present invention, since the manufacturing is performed using the droplet discharge method in which the landing positions of the functional liquid droplets on the substrate are appropriately controlled, the electro-optical device itself is reliably manufactured. be able to.
[Brief description of the drawings]
FIG. 1 is a plan view schematically showing a droplet discharge device according to an embodiment of the present invention.
FIGS. 2A and 2B are diagrams showing a droplet discharge head according to the embodiment, wherein FIG. 2A is a perspective view and FIG. 2B is a schematic plan view.
FIG. 3 is a plan view showing an alignment mask according to the embodiment.
FIG. 4 is a block diagram illustrating a control configuration of the droplet discharge device according to the embodiment.
FIG. 5 is a flowchart illustrating a processing flow of a dot position correction method of the droplet discharge device according to the embodiment.
FIG. 6 is a diagram schematically illustrating an imaging screen of the recognition camera according to the embodiment.
FIG. 7 is an explanatory diagram showing a method of acquiring correction data outside a correction data acquisition point.
FIG. 8 is an explanatory diagram showing an example of an actual drawing operation using the dot position correction method of the droplet discharge device according to the embodiment.
FIG. 9 is a plan view of a droplet discharge device according to a second embodiment.
FIG. 10 is a cross-sectional view illustrating a structure of a liquid crystal display device.
FIG. 11 is a cross-sectional view illustrating a structure of an organic EL device.
[Explanation of symbols]
1 Droplet ejection device
2 XY moving mechanism (XY moving mechanism)
3 X axis table
4 Y axis table
5 Main carriage (head carriage)
6 droplet ejection head
8 Recognition camera
34 Head Angle Fine Adjustment Mechanism (XY Movement Mechanism)
45 nozzle row
46 nozzle
50 Alignment mask
52 Flushing receiver
57 Regulation mark
58 fiducial mark
101 camera carriage
450 liquid crystal display
500 Organic EL device
P lattice point
Q inspection area
W substrate

Claims (21)

A drawing operation of selectively discharging a functional liquid in a dot form from a nozzle row of the droplet discharge head while moving the droplet discharge head relatively to the set work by an X / Y movement mechanism is performed by a discharge operation. A dot position correction method for a droplet discharge device performed based on pattern data,
A mask introducing step of setting an alignment mask, which has a plurality of inspection areas each having a reference mark, in a lattice shape, instead of the work,
A dot drawing step of performing the drawing operation based on the alignment ejection pattern data corresponding to the plurality of reference marks, and drawing test dots in each of the test areas;
A recognition step of recognizing an image of the position of each inspection dot with respect to each of the reference marks,
A data correction step of correcting the ejection pattern data based on a recognition result in the recognition step;
A dot position correction method for a droplet discharge device, comprising: In the recognition step, a recognition camera for performing image recognition is moved by the XY movement mechanism,
2. The dot position correcting method for a droplet discharge device according to claim 1, wherein the method is performed by simultaneously capturing each of the reference marks and each of the inspection dots within a visual field of the recognition camera. The XY moving mechanism is configured to be able to move the droplet discharge head and the recognition camera independently of each other,
3. The dot position correcting method for a droplet discharge device according to claim 2, further comprising a maintenance step of performing a maintenance process while keeping the droplet discharge head in a non-moving state, in parallel with the recognition step. . The Y-axis direction is a main scanning direction of the droplet discharge head, and the X-axis direction is a sub-scanning direction of the droplet discharge head.
The ejection pattern data includes ejection timing data relating to ejection driving of the droplet ejection head and head movement pattern data relating to relative movement of the droplet ejection head by the XY movement mechanism,
The data correction step corrects the ejection timing data for a dot position shift in the Y-axis direction, and corrects the head movement pattern data for a dot position shift in the X-axis direction. 4. The dot position correcting method for a droplet discharge device according to claim 1, wherein pattern data is corrected. The droplet discharge head is moved relative to the set workpiece by the XY moving mechanism in the Y-axis direction as the main scanning direction and the X-axis direction as the sub-scanning direction. A dot position correction method for a droplet discharge device that performs a drawing operation for selectively discharging a functional liquid in a dot form from a nozzle row based on discharge pattern data,
A mask introducing step of setting an alignment mask, which has a plurality of inspection areas each having a reference mark, in a lattice shape, instead of the work,
Performing the drawing operation based on the alignment ejection pattern data corresponding to the plurality of reference marks, and using at least two nozzles of the nozzle row, testing dots including at least two testing dots in each testing area. A dot drawing process for drawing a group,
A recognition step of recognizing an image of the position of each of the inspection dot groups with respect to each of the reference marks,
Based on the recognition result in the recognition step, the XY moving mechanism generates angle correction data for relatively correcting the rotation of the droplet discharge head in the Θ-axis direction, and takes into account the angle correction data. A data correction step of correcting the ejection pattern data by
A dot position correction method for a droplet discharge device, comprising: 6. The dot position correcting method for a droplet discharge device according to claim 5, wherein the at least two nozzles used in the dot drawing step are two nozzles located at the outermost ends in the nozzle row. . 7. The dot position correcting method for a droplet discharge device according to claim 6, wherein the length of the inspection area in the X-axis direction and the length of the nozzle row are set substantially equal. The inspection dot group is composed of three or more inspection dots,
The recognition step performs image recognition by classifying the three or more inspection dots into a plurality of partial inspection dot groups,
6. The dot position correction method for a droplet discharge device according to claim 5, wherein in the data correction step, the angle correction data is generated by averaging the recognition results of the plurality of partial inspection dot groups. In the recognition step, the recognition camera that performs image recognition is moved in the X-axis direction and the Y-axis direction by the XY movement mechanism,
The dot of the droplet discharge device according to any one of claims 5 to 8, wherein the detection is performed by simultaneously capturing each of the reference marks and each of the inspection dot groups in the field of view of the recognition camera. Position correction method. Each of the reference marks is configured as a plurality of reference mark groups including a plurality of reference marks dispersedly arranged in a circumferential direction around a drawing position of the inspection dot in the alignment ejection pattern data. The dot position correction method for a droplet discharge device according to claim 9. The XY moving mechanism is configured to be able to move the droplet discharge head and the recognition camera independently of each other,
The dot position of the droplet discharge device according to claim 9, further comprising a maintenance step of performing a maintenance process while keeping the droplet discharge head in a non-moving state, in parallel with the recognition step. Correction method. The ejection pattern data includes ejection timing data related to ejection driving of the droplet ejection head and head movement pattern data related to relative movement of the droplet ejection head by the XY movement mechanism.
The data correction step corrects the ejection timing data for a dot position shift in the Y-axis direction by taking into account the angle correction data, and corrects the head movement pattern for a dot position shift in the X-axis direction. 12. The dot position correction method for a droplet discharge device according to claim 5, wherein the discharge pattern data is corrected by correcting data. 13. The dot position correction method for a droplet discharge device according to claim 1, wherein the alignment mask has at least surfaces of the plurality of inspection areas subjected to a water-repellent treatment. The dot drawing step, an inspection drawing step of performing the drawing operation on each of the inspection areas,
14. A flushing step of performing a flushing operation of discharging a functional liquid from all nozzles of the droplet discharge head at a position off the plurality of inspection areas on the alignment mask. The dot position correction method for a droplet discharge device according to any one of the above. In the droplet discharge head, the plurality of nozzle rows are configured in parallel with each other,
15. The dot position correction method for a droplet discharge device according to claim 1, wherein the data correction step is performed by correcting the discharge pattern data for each of the plurality of nozzle rows. An alignment mask for use in the dot position correction method for a droplet discharge device according to any one of claims 1 to 15. Using the dot position correction method of the droplet discharge device according to any one of claims 1 to 4,
A droplet discharge method, wherein the drawing operation is performed on a workpiece set in the droplet discharge device based on corrected discharge pattern data. Using the dot position correction method of the droplet discharge device according to any one of claims 5 to 12,
A droplet discharge method, wherein the drawing operation is performed on a workpiece set in the droplet discharge device based on the angle correction data and the corrected discharge pattern data. 19. A film forming unit formed by using the liquid droplet discharging method according to claim 17 or 18 and forming a functional liquid selectively discharged from the liquid droplet discharging head on the substrate serving as the work. Electro-optical device. 19. A film forming section is formed by selectively discharging a functional liquid from the droplet discharge head on the substrate serving as the work using the droplet discharge method according to claim 17 or 18. A method for manufacturing an electro-optical device. An electronic apparatus comprising the electro-optical device according to claim 19.

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