1. Field of the Invention
The present invention relates to a photosensitive layer laminator and photosensitive layer laminating method. More particularly, the present invention relates to a photosensitive layer laminator and photosensitive layer laminating method in which a photosensitive material can be handled easily, a photosensitive layer can be transferred to an entirety of a large transfer area, and modification of mechanisms can be easy when necessitated.
2. Description Related to the Prior Art
A color filter for use in a liquid crystal display device, plasma display device and the like is produced by utilizing photosensitive material. For example, three photosensitive layers for primary colors of red, green and blue are overlaid on a substrate of glass, resin or other rigid material. Those are referred to as photo resist. A laminated panel is obtained, and subjected to exposure and photographic processing to produce the color filter according to a process of photolithography. For example, U.S. Pat. No. 6,684,925 (corresponding to JP-A 2002-148794) discloses a photosensitive layer laminator for producing a laminated panel. A photosensitive material includes a support film, and a photosensitive layer of resin overlaid on the support film. The photosensitive material and the substrate are respectively transported. Lamination rolls or heat/pressure rollers are disposed on a transporting path, and operated to transfer and laminate the photosensitive layer to the substrate.
A supply unit of the photosensitive layer laminator is loaded with one roll of the photosensitive material having a great length sufficient for a high number of sheets. A width of the photosensitive material is predetermined and depends on a width of a transfer region defined on the substrate. In operation, the photosensitive material is unwound from the roll, and subjected to half cutting to form cuts through the photosensitive layer according to a length of the substrate. Then the photosensitive material is fed to the path. The heat/pressure rollers transfer the photosensitive layer to the substrate, before the support film is peeled from the photosensitive layer to obtain the laminated panel.
Recently, display devices of an enlarged panel size have been widely available in any one of types including a liquid crystal display device, plasma display device and the like. A size of the substrate has been greater, to enlarge a width of a transfer region. The larger width of the transfer region requires a greater width of the photosensitive material. However, a roll size of the photosensitive material must be larger, to enlarge mechanisms for transporting the roll, and those for advancing the photosensitive material. A cost for modifying the photosensitive layer laminator will be considerably high. This is a serious problem inconsistent to reducing the manufacturing cost of a laminated panel as product. Also, a greater width of the photosensitive material causes problems in greater weight and more frequent occurrence of wrinkles. The handling of the photosensitive material becomes considerably difficult.
In view of the foregoing problems, an object of the present invention is to provide a photosensitive layer laminator and photosensitive layer laminating method in which a photosensitive material can be handled easily, a photosensitive layer can be transferred to an entirety of a large transfer area, and modification of mechanisms can be easy when necessitated.
In order to achieve the above and other objects and advantages of this invention, a photosensitive layer laminator for transferring a photosensitive layer from a photosensitive material to a substrate is provided, the photosensitive material including a support, and the photosensitive layer overlaid on the support and containing resin. In the photosensitive layer laminator, a laminating mechanism applies the photosensitive layer of plural photosensitive materials to a transfer region on the substrate by applying heat and pressure to the plural photosensitive materials and the substrate. A photosensitive material feeder supplies the laminating mechanism with the plural photosensitive materials directed substantially in parallel with one another and including first and second photosensitive materials, the plural photosensitive materials having a width smaller than a width of the transfer region. A substrate feeder supplies the laminating mechanism with the substrate in placement on the plural photosensitive materials.
The laminating mechanism includes at least one heat/pressure roller. The photosensitive material feeder includes a first feeding mechanism for unwinding the first photosensitive material from a first photosensitive material roll, and supplying the first photosensitive material to a first roller portion of the heat/pressure roller. A second feeding mechanism unwinds the second photosensitive material from a second photosensitive material roll, and supplies the second photosensitive material to a second roller portion of the heat/pressure roller which extends from the first roller portion.
A sum of the width of the at least first and second photosensitive materials is equal to or less than the width of the transfer region.
Furthermore, a tension adjuster adjusts tension applied to the first and second photosensitive materials in an upstream direction from the laminating mechanism.
Each of the first and second feeding mechanisms includes a tension roller for applying first and second tension to the first and second photosensitive materials upstream from the laminating mechanism. The tension adjuster includes a tension detector for measuring the first and second tension applied to the first and second photosensitive materials. A controller is responsive to information from the tension detector, for controlling the tension roller, and setting the first and second tension substantially equal to one another.
Each of the first and second photosensitive materials includes cover film, overlaid on the photosensitive layer, for protection thereof. Furthermore, a cover peeler peels the cover film from the first and second photosensitive materials transported to the substrate.
Furthermore, at least one half cutter cuts the photosensitive layer in the first and second photosensitive materials with the support uncut and in a predetermined size adapted to the transfer region with reference to a transporting direction.
The at least one half cutter comprises at least two half cutters associated with respectively the first and second feeding mechanisms, for keeping adjustable a size of the photosensitive layer to be transferred individually from one another.
A plurality of photosensitive layer portions constituted by the photosensitive layer and having the predetermined size are arranged in the transporting direction and transferred to the transfer region commonly.
The laminating mechanism produces a laminated panel having the substrate and the photosensitive layer. Furthermore, a cooler cools the laminated panel from the laminating mechanism. A support peeler for peeling the support from the photosensitive layer of the laminated panel from the cooler.
The photosensitive layer is colorable in a predetermined color which is different between the at least first and second photosensitive materials.
In one preferred embodiment, the photosensitive layer is colorable in a predetermined color which is selected from three primary colors and black color.
The at least first and second photosensitive materials are different in the width.
The photosensitive layer of the first photosensitive material is transferred for forming a predetermined visible pattern. The second photosensitive material has a width smaller than a width of the first photosensitive material, and has the photosensitive layer adapted to form a positioning indicia for positioning the visible pattern being formed.
In one aspect of the invention, a photosensitive layer laminating method of transferring a photosensitive layer containing resin to a transfer region on a substrate is provided. In the photosensitive layer laminating method, at least first and second photosensitive materials are transported to the substrate, wherein the first and second photosensitive materials respectively include a support and the photosensitive layer overlaid thereon, have a width smaller than a width of the transfer region, and are disposed to extend along one another. The photosensitive layer from the first and second photosensitive materials is applied to the transfer region on the substrate with heat and pressure.
The first and second photosensitive materials are unwound from respectively first and second photosensitive material rolls. The applying step is effected in first and second laminating domains which are arranged in a direction crosswise to transport of the first and second photosensitive materials, and are supplied with respectively the first and second photosensitive materials.
The above objects and advantages of the present invention will become more apparent from the following detailed description when read in connection with the accompanying drawings, in which:
In
In
After the baking, the substrate 22 with filter patterning of the red color is loaded in the photosensitive layer laminator 2 again. The photosensitive material rolls 18a and 18b for the green color are set, to transfer the green photosensitive layer to the substrate 22. In a similar manner to the red photosensitive layer, the green photosensitive layer is patterned for the filter patterning, and fixed by baking. After this, the substrate 22 with filter patterning of the blue color is loaded in the photosensitive layer laminator 2 again. The blue photosensitive layer is transferred to the substrate 22. In a manner similar manner, the blue photosensitive layer is patterned, and fixed by baking. After this filter patterning of the three colors, the black (BK) photosensitive layer is transferred to the substrate 22 in order to fill fine gaps between the patterned portions.
In
The preheater 11 includes a substrate transporting mechanism 24 and heater units 25 and 26. The substrate transporting mechanism 24 is constituted by a flotation blower 27 of a board form and a number of transporting rollers 28. The flotation blower 27 is disposed under a path for the substrate 22, and opposed to a transfer surface of the substrate 22, blows clean air over the transfer surface to float the substrate 22.
The transporting rollers 28 contact lateral edge operations of the transfer surface of the substrate 22 being floated, and rotate to transport the substrate 22 toward the laminating mechanism 12 for heat and pressure. There occurs no transfer to those edge portions of the transfer surface. In those portions, the transporting rollers 28 does not contact the photosensitive layer 20. The transporting rollers 28 are structurally flange-formed rollers, have a flange (not shown), which guides the substrate 22 and regulates the position of the substrate 22 in the width direction.
The heater units 25 and 26 are arranged above and below the path for the substrate 22 in the substrate transporting mechanism 24, and disposed in suitable numbers of a plurality. The heater units 25 and 26 heat the substrate 22 up to the temperature in a range of, for example, 50–110° C. The substrate 22 heated by the preheater 11 is transported by the transporting rollers 28 to the laminating mechanism 12.
The laminating mechanism 12 is constituted by a heat/pressure roller set 29 and backup rollers 30. In the heat/pressure roller set 29, a first heat/pressure roller 29a contacts the substrate 22 as lamination roll. A second heat/pressure roller 29b contacts the first and second photosensitive materials 17a and 17b as lamination roll. A heater is incorporated in each one of the heat/pressure rollers 29a and 29b and the backup rollers 30. The heat/pressure roller set 29 squeezes and transports the substrate 22 and the first and second photosensitive materials 17a and 17b, so as to attach the first and second photosensitive materials 17a and 17b to the substrate 22 with heat and pressure. The backup rollers 30 are caused to rotate by contact of the heat/pressure rollers 29a and 29b, and uniformize the force for lamination with heat and pressure by suppressing flexing or distortion of the heat/pressure rollers 29a and 29b.
A half cut line formed by a half cutter blade group 45 in the first and second photosensitive materials 17a and 17b will be described later. When the half cut line moves past a predetermined position in the laminating mechanism 12, then a start signal is input to the substrate transporting mechanism 24. The photosensitive layer 20 is transferred from the first and second photosensitive materials 17a and 17b to the substrate 22 in a state with the half cut line positioned on the substrate 22. At this time, the support 19 is transported in the downstream direction from the heat/pressure roller set 29 according to movement of the substrate 22.
The cooler 13 includes a cool gas blower 31 of a board form, and transporting rollers 32. Cool air is passed through a HEPA (high efficiency particulate air) filter to obtain clean cool air, which is directed by the cool gas blower 31 to blow the substrate 22. Thus, the substrate 22 is cooled to the room temperature which may be 30° C. or lower while transported by the transporting rollers 32.
The support peeler 14 is constituted by a peeling roller 33 and a support sheet winder 34. The peeling roller 33 consecutively peels the support 19 from the substrate 22 to be a laminated panel. A support sheet spindle 34a of the winder 34 winds and withdraws the support 19 in a roll form. A motor (not shown) causes the spindle 34a to rotate. The motor is controlled for its torque, in order to maintain tension applied to the support 19 at a constant level in a zone downstream from the heat/pressure roller set 29, so as to prevent occurrence of flexing or looseness in the support 19.
The panel ejector 15 is positioned downstream from the support peeler 14, and has a flotation blower 35 of a board form. The flotation blower 35 is structurally the same as the flotation blower 27 in the preheater 11. Also, a robot hand 36 is disposed in the panel ejector 15. The laminated panel including the substrate 22, when transported from the support peeler 14 to the panel ejector 15, is sucked by a suction device in the robot hand 36, and picked up and ejected.
In
Each of the half cutters 39 and 40 includes the half cutter blade group 45. The first photosensitive material 17a has a photosensitive layer 20a and cover film 21a. The second photosensitive material 17b has a photosensitive layer 20b and cover film 21b. The half cutter 39 cuts the photosensitive layer 20a and the cover film 21a, but keeps the support 19 uncut. Similarly, the half cutter 40 cuts the photosensitive layer 20b and the cover film 21b, but keeps the support 19 uncut. A relationship between the half cutters 39 and 40 is based on a size of a transfer region 22a of the substrate 22. The half cutter blade group 45 includes two blades with cutting edges extending in the width direction of the first and second photosensitive materials 17a and 17b. An interval between the two blades is defined according to an interval or period of the transport of the substrate 22 one after another. To be precise, the interval between the blades is set equal to an interval between a rear end of the transfer region 22a of a first substrate and a front end of the transfer region 22a of a second substrate succeeding to the first. The two are actuated at the same time, to form two cuts simultaneously for the appropriate positions.
The cover peeler 41 peels the cover film 21a from the first photosensitive material 17a after cutting of the photosensitive layer 20a. The cover peeler 42 peels the cover film 21b from the second photosensitive material 17b after cutting of the photosensitive layer 20b. Each of the cover peelers 41 and 42 is loaded with a peeling tape roll 46. A pressure-sensitive adhesive tape 47 is unwound from the peeling tape roll 46. A pressure roller 48 presses the adhesive tape 47 on to the cover film 21. The adhesive tape 47 adheres to the cover film 21. A tape spindle 49 winds up and withdraws the adhesive tape 47, so that the adhesive tape 47 takes away the cover film 21 for withdrawal.
The tension adjuster 43 is constituted by a tension roller 50, a motor 52 and a tension sensor or detector 54. Similarly, the tension adjuster 44 includes a tension roller 51, a motor 53 and a tension sensor or detector 55. The tension rollers 50 and 51 operate according to tension detected by the tension detectors 54 and 55, keep constant the tension of a portion of the first and second photosensitive materials 17a and 17b positioned upstream from the heat/pressure roller set 29, so as to prevent flexing or looseness of the first and second photosensitive materials 17a and 17b. An example of the tension detectors 54 and 55 is a tension pickup (TP) device having a rotatable roll with a small diameter. There is a controller 56 as illustrated in
A position control device 57 is a single device for the first and second photosensitive materials 17a and 17b. The position control device 57 operates to regulate a distance between the first and second photosensitive materials 17a and 17b at a predetermined level, to stabilize the transport of the first and second photosensitive materials 17a and 17b. It is to be noted that the position control device 57 may be added to other positions in a suitable manner to keep high precision in transporting the first and second photosensitive materials 17a and 17b.
In
W2≦½×W1
The first and second photosensitive materials 17a and 17b are transported in parallel with one another. The photosensitive layer 20 can be transferred to nearly the entire area of the transfer region 22a. Thus, the parallel supply of the photosensitive materials having the smaller width than the transfer region 22a is effective in transferring the photosensitive layer to the entirety of the transfer region 22a. There is no need of using a differently designed photosensitive material with a greater width.
In
The operation of the above construction is hereinafter described. The supply robot hand 23 in the substrate feeder 10 supplies the preheater 11 with the substrate 22. The substrate 22 in the preheater 11 is initially heated by the heater units 25 and 26, and sent to the laminating mechanism 12 for heat and pressure. The first and second feeding mechanisms 16a and 16b supply the first and second photosensitive materials 17a and 17b to the substrate 22 in the laminating mechanism 12 in a parallel orientation with one another.
In a step prior to supply of the laminating mechanism 12 with the first and second photosensitive materials 17a and 17b, the controller 56 controls the first and second feeding mechanisms 16a and 16b in a manner separate from one another to pre-treatment of the first and second photosensitive materials 17a and 17b. The half cutter blade group 45 in each of the half cutters 39 and 40 forms cuts in the first and second photosensitive materials 17a and 17b according to a length of the transfer region 22a of the substrate 22, before transport to the cover peelers 41 and 42. The cover peelers 41 and 42 peel an uppermost film piece constituted by the cover films 21a and 21b from the photosensitive layer 20a and 20b as overlaid element in the first and second photosensitive materials 17a and 17b. The first and second photosensitive materials 17a and 17b after moving past the cover peelers 41 and 42 are transported to the laminating mechanism 12 with their tension kept constant and equal by the tension adjusters 43 and 44.
The first photosensitive material 17a supplied from the first feeding mechanism 16a is transported through the heat/pressure roller set 29 of the laminating mechanism 12 in a state positioned at the transfer region 22a of the substrate 22. The photosensitive layer 20a in the first photosensitive material 17a is transferred to the transfer region 22a. Similarly, the second photosensitive material 17b from the second feeding mechanism 16b moves through the heat/pressure roller set 29 of the laminating mechanism 12 as positioned at the transfer region 22a of the substrate 22. The photosensitive layer 20b in the second photosensitive material 17b is transferred to the transfer region 22a. The substrate 22 after the transfer of the photosensitive layer 20a or 20b is sent to the cooler 13, cooled by blowing cool gas from the cool gas blower 31, and moved to the support peeler 14. The support peeler 14 winds up the support from the first and second photosensitive materials 17a and 17b on the spindle 34a, to peel the support. A laminated panel having the substrate 22 after peeling of the support of the first and second photosensitive materials 17a and 17b is moved to the panel ejector 15, is grasped by the robot hand 36 upwards according to suction, and is ejected.
It is possible in the photosensitive material feeder 16 that the first and second photosensitive materials 17a and 17b being transported together have a width smaller than a width of the transfer region 22a of the substrate 22. Thus, it is unnecessary to raise a width or size of a structure for feeding the photosensitive material. The entire area of the substrate can be laminated easily without largely modifying the structure of the laminator. Also, the first and second photosensitive materials 17a and 17b with the smaller width than the conventional photosensitive material are remarkably easy to handle. Occurrence of wrinkles of the first and second photosensitive materials 17a and 17b can be suppressed efficiently, to cause handling with great ease without lowering quality.
In the above embodiment, various mechanisms for the supply are associated with the photosensitive material rolls 18a and 18b as plural sets in a separate manner from one another, including the tension adjusters 43 and 44, the half cutters 39 and 40, and the cover peelers 41 and 42. However, a single set of mechanisms can be used for the plural photosensitive materials. However, the separate sets of the half cutters 39 and 40 are advantageous because the individual control enables fine adjustment of the production of panels. In the above embodiment, one operation of the transfer for the lamination is a multi-sheet form for producing four panels. The length of the photosensitive layer to be transferred at one time is determined by a length cut by the half cutting. Therefore, adjustment of a cutting position makes it possible to, for example, transfer an amount of two panels for a first photosensitive material, and to transfer an amount of only one panel for a second photosensitive material. There are effects in reducing load in the developing process.
In the above embodiment, the second photosensitive material 17b is for the same color as that for the first photosensitive material 17a. In
In the above embodiment, the second photosensitive material 17b has the width which is equal to that of the first photosensitive material 17a, and is equal to or less than ½ of the width W1 of the transfer region 22a. However, the width of the second photosensitive material 17b may be different from that of the first photosensitive material 17a. A width of the photosensitive material 17a or 17b may be more than ½ of the width of the transfer region 22a. For example, a width of the first photosensitive material 17a can be ⅔ as much as the width of the transfer region 22a, a width of the second photosensitive material 17b being ⅓ as much as the width of the transfer region 22a. This is advantageous in treating raw material with a temporarily small width. Changes in the width make it possible to utilize such raw material in spite of its small width in view of higher productivity in the manufacturing line.
In
Note that according to the above embodiment, there is a gap between the first and second photosensitive materials 17a and 17b being transported together. However, such a gap may not exist. The first and second photosensitive materials 17a and 17b can run in such a manner that their longitudinal edges can contact one another exactly, or may overlap on one another at a small area.
In the above embodiment, paths of the transport of the first and second feeding mechanisms 16a and 16b are parallel with one another. However, the first feeding mechanism 16a may have a differently formed path from that of the second feeding mechanism 16b. For example, at least one of the first and second feeding mechanisms 16a and 16b can have a form to turn the photosensitive material 17a or 17b with 90 degrees, and can be disposed in horizontally separate zones, or vertically separate zones.
The transfer of the photosensitive material to a substrate according to the invention may be used in any of various panels in the fields of imaging or electricity, for example, panels for a liquid crystal display device, a plasma display device, and an organic electro luminescence (EL) panel, and also for a printed wiring board, a thin film transistor (TFT) board, and the like.
Although the present invention has been fully described by way of the preferred embodiments thereof with reference to the accompanying drawings, various changes and modifications will be apparent to those having skill in this field. Therefore, unless otherwise these changes and modifications depart from the scope of the present invention, they should be construed as included therein.
Number | Date | Country | Kind |
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2003-126287 | May 2003 | JP | national |
Number | Name | Date | Kind |
---|---|---|---|
4495014 | Gebrian et al. | Jan 1985 | A |
4714504 | Cummings et al. | Dec 1987 | A |
5437960 | Nagate et al. | Aug 1995 | A |
5720847 | Nagate et al. | Feb 1998 | A |
5772839 | Nagate et al. | Jun 1998 | A |
6500291 | Okada et al. | Dec 2002 | B1 |
6684925 | Nagate et al. | Feb 2004 | B2 |
Number | Date | Country |
---|---|---|
04323031 | Nov 1992 | JP |
06349727 | Dec 1994 | JP |
Number | Date | Country | |
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20040219450 A1 | Nov 2004 | US |