JP5354803B2 - Exposure equipment - Google Patents

Abstract

Disclosed is an exposure system with a lens assembly (11) adapted to be movable in the direction of an arrow (B) within a plane which is parallel to the plane of a workpiece to be exposed to light and the plane of a photo mask. The lens assembly has a plurality of unit lens assemblies (11A to 11C) in which a plurality of lens groups (15) are arrayed at certain pitches in a direction intersecting the direction of the arrow (B) to form a plurality of lens arrays (16), the lens groups being capable of focusing an erect image of the mask pattern of the photo mask at the same magnification on the surface of the workpiece being exposed to light. Furthermore, each of the plurality of unit lens assemblies (11A to 11C) is formed by shifting the lens arrays (16) from each other by a certain amount in the direction intersecting the direction of the arrow (B) so that each lens group (15) of each of the lens arrays (16) is aligned in parallel to an axial line O-O that diagonally intersects the direction of the arrow (B). The unit lens assemblies (11A to 11C) are further arranged in one line so that mutually adjacent ends (11Aa, 11Ba, 11Bb, 11Ca) are cut in parallel to the axial line O-O, and the lens groups (15) of each of the lens arrays (16) are arrayed at certain pitches in the direction intersecting the direction of the arrow (B). This arrangement allows a large-area workpiece to be exposed to a non-periodic pattern at high resolution.

Description

  The present invention relates to an exposure apparatus that irradiates an object to be exposed held on a stage with exposure light via a photomask to expose and form a predetermined pattern. More specifically, the present invention relates to an aperiodic pattern in an object to be exposed in a large area. The present invention relates to an exposure apparatus that is capable of performing the above exposure with high resolution.

  This type of conventional exposure apparatus is an exposure apparatus that intermittently irradiates an exposure object conveyed at a constant speed through a photomask and exposes the mask pattern of the photomask to a predetermined position. A plurality of light sources arranged in a direction substantially perpendicular to the transport direction, the exposure position by the photomask, or a position in front of the exposure position in the transport direction of the object to be exposed. A first imaging means having a light receiving element and an exposure position by the photomask, or a position on the nearer side of the exposure object in the transport direction than the exposure position, are disposed and are substantially parallel to the transport direction. The second imaging means having a plurality of light receiving elements arranged in a row, the object to be exposed and the photomask are relatively moved in a direction substantially perpendicular to the transport direction to correct the exposure position by the photomask. When a first reference position for exposure position correction provided in advance on the object to be exposed is detected by the alignment unit and the first imaging unit, the driving of the alignment unit is controlled based on the first reference position. Control means for controlling the irradiation timing of the exposure light based on the second reference position for extracting the irradiation timing of the exposure light provided in advance on the exposure object by the second imaging means; (See, for example, Patent Document 1).

JP 2008-76709 A

  However, in such a conventional exposure apparatus, when exposing a pattern having periodicity to an object to be exposed (substrate), the exposure light irradiation timing is set while conveying the substrate in one direction at a constant speed. Although it can be easily performed only by controlling at a predetermined cycle, exposure of a non-periodic pattern is difficult. In addition, because exposure is performed with the photomask close to and opposed to the substrate, the presence of a viewing angle (collimation half angle) in the light source light irradiated to the photomask blurs the pattern image on the substrate and lowers the resolution. However, there is a fear that a fine pattern cannot be formed by exposure.

  Such a problem can be dealt with by using a stepper exposure apparatus that performs exposure by reducing and projecting an image of a photomask on a substrate with an imaging lens. For example, a large area of 1 m square or more is used. In the case of performing exposure on a substrate, there is a problem that the lens diameter to be used becomes large corresponding to the size of the substrate and becomes expensive.

  Therefore, the present invention addresses such problems and an object of the present invention is to provide an exposure apparatus capable of exposing a non-periodic pattern on a large-area exposure object with high resolution.

  In order to achieve the above object, an exposure apparatus according to the present invention is parallel to a surface of an object to be exposed and a surface of the photomask between a stage on which the object to be exposed is mounted and a photomask on which a mask pattern is formed. A plurality of lens groups formed so as to be movable in a plane and capable of forming an equal-size erect image of the mask pattern of the photomask on the surface of the object to be exposed, in a direction that intersects the moving direction. A plurality of unit lens assemblies arranged in a pitch to form a plurality of lens rows are arranged to be arranged in a row in a direction intersecting with the moving direction, and each unit lens assembly includes a lens assembly. Each lens group is shifted by a certain amount from each other in the direction intersecting the moving direction so that each lens group is arranged in parallel to an axis that obliquely intersects the moving direction of the lens assembly. In addition, the configuration is such that end portions adjacent to each other are cut away in parallel to the axis, and the lens groups of each lens array are arranged at a constant arrangement pitch over the entire lens assembly. Is.

  With such a configuration, each lens array is moved in such a manner that a plurality of lens groups arranged at a constant arrangement pitch of the plurality of lens arrays are aligned in parallel to an axis that obliquely intersects the moving direction of the lens assembly. A plurality of unit lens assemblies that are formed by shifting each other by a certain amount in a direction crossing the direction and cutting the end portions adjacent to each other in parallel to the axis line, the lens group of each lens row as a whole. A mask pattern of a photomask while moving lens assemblies arranged in a line so as to be arranged at a constant arrangement pitch over a surface parallel to the surface of the object to be exposed and the surface of the photomask mounted on the stage Is formed on the surface of the object to be exposed, and an aperiodic pattern is exposed on the object to be exposed.

  The unit lens assemblies are obtained by shifting the lens rows so that a part of the lens groups overlap each other when viewed in the moving direction of the lens assembly. As a result, one lens row of adjacent lens rows is shifted by a predetermined amount in the lens group arrangement direction so that a part of each lens group of each lens row overlaps when viewed in the direction of movement of the lens assembly. The mask pattern of the photomask is exposed on the object to be exposed while moving the lens assembly.

  Further, the lens assembly includes a first lens array, a second lens array, a third lens array, and a fourth lens array in which a plurality of convex lenses are formed so as to correspond to the front and back surfaces of a transparent substrate. And an intermediate inverted image of the mask pattern of the photomask is formed between the second lens array and the third lens array. Accordingly, the first, second, third and fourth lens arrays formed with a plurality of convex lenses corresponding to each other on the front and back surfaces of the transparent substrate are overlapped with each other so that the optical axes of the corresponding convex lenses coincide with each other. A lens assembly configured to form an intermediate inverted image of the mask pattern of the photomask between the second lens array and the third lens array, so that the mask pattern formed on the photomask is an equal magnification. A standing image is formed on the surface of the object to be exposed.

  The lens assembly is provided with a first aperture having a predetermined shape adjacent to the surface of the convex lens located on the upstream side in the light traveling direction of the third lens array, and an exposure area by the unit lens is provided. This is limited to the center of the lens. As a result, the exposure area of the unit lens is defined by the first aperture having a predetermined aperture provided close to the surface of the convex lens positioned upstream of the light traveling direction of the third lens array of the lens assembly. Limit to the center.

  In addition, the opening of the first diaphragm is an opening having a rectangular shape in plan view, and the area of a portion that overlaps with a part of the opening of the first diaphragm adjacent in the moving direction of the lens assembly is the entire overlapping part. A part of the light is shielded so as to be half the area. As a result, in the rectangular opening in plan view, the area of the portion that overlaps with a part of the opening of the first aperture that is adjacent when viewed in the moving direction of the lens assembly is half the area of the entire overlapping portion. The exposure area is limited by the opening of the first diaphragm having a shape in which the portion is shielded, and the mask pattern of the photomask is exposed on the surface of the object to be exposed. In this case, a predetermined amount of exposure is performed by overexposure of a lens group existing ahead of the moving direction of the lens assembly.

  Further, the lens assembly is provided with a second diaphragm that restricts the diameter of the light beam in the vicinity of the lens surface upstream of the light traveling direction of the fourth lens array. Thus, the diameter of the light beam is limited by the second diaphragm provided in the vicinity of the lens surface upstream of the light traveling direction of the four lens arrays.

  The stage is capable of transporting the object to be exposed in one direction, and the lens assembly moves in a state where the movement of the stage is temporarily stopped. Accordingly, the stage that is transporting the object to be exposed in one direction is temporarily stopped, and the lens assembly is moved in this stopped state to expose the mask pattern of the photomask on the object to be exposed.

  According to the first aspect of the present invention, while moving the lens assembly formed so as to be able to form an equal-magnification erect image of the mask pattern formed on the photomask on the surface of the exposure object in parallel with the surface of the photomask. Exposure can be performed, and even if the mask pattern is an aperiodic pattern, exposure can be performed with high resolution. In this case, the lens assembly may be smaller than the size of the photomask. Therefore, the size of the lens assembly to be used can be reduced even when the size of the photomask is increased corresponding to the exposure object having a large area, and the component cost can be reduced. Thereby, the manufacturing cost of the apparatus can be reduced. In addition, since the lens assembly is a plurality of unit lens assemblies arranged in a row, the moving distance of the lens assembly can be made shorter than that in which a plurality of unit lens assemblies are arranged in a staggered manner. The tact time of the process can be shortened.

  According to the second aspect of the present invention, a mask pattern having a size larger than the size of the lens can be continuously connected and exposed without being interrupted.

  Furthermore, according to the invention of claim 3, a lens assembly in which a plurality of unit lenses are arranged in a plane can be easily formed. Therefore, the manufacturing cost of the lens assembly can be reduced.

  According to the fourth aspect of the invention, it is possible to form an equal-magnification erect image of the mask pattern of the photomask on the surface of the object to be exposed with high accuracy by eliminating the influence of lens aberration. Therefore, the exposure pattern formation accuracy can be improved.

  According to the fifth aspect of the present invention, overexposure can be prevented even when overexposure is performed to connect exposure patterns. Therefore, the exposure pattern formation accuracy can be further improved.

  Furthermore, according to the invention which concerns on Claim 6, a light beam diameter can be restrict | limited and the resolving power by the lens group of a lens assembly can be improved more.

  According to the seventh aspect of the present invention, exposure can be performed while continuously supplying the object to be exposed, and the efficiency of the exposure process can be improved.

It is a front view which shows embodiment of the exposure apparatus by this invention. It is a top view of FIG. It is a top view which shows the board | substrate for thin film transistors used for the exposure apparatus of this invention. It is a top view which shows one structural example of the photomask for signal terminals used for the exposure apparatus of this invention. It is a top view which shows one structural example of the lens assembly for signal terminals used for the exposure apparatus of this invention. It is a figure which shows one structural example of the unit lens assembly for signal terminals of the said lens assembly for signal terminals, (a) is a top view, (b) is a front view. It is a top view explaining opening of the 1st stop of the lens group of the unit lens assembly for signal terminals. It is explanatory drawing which shows exposure by two lens groups adjacent to the moving direction of the said lens assembly for signal terminals. It is a top view which shows the other shape of opening of the said 1st aperture_diaphragm | restriction. It is a top view which shows one structural example of the photomask for scanning terminals used for the exposure apparatus of this invention. It is a figure which shows one structural example of the unit lens assembly for scanning terminals of the lens assembly for scanning terminals used for the exposure apparatus of this invention, (a) is a top view, (b) is a front view. It is explanatory drawing shown about assembly adjustment of the said lens assembly for signal terminals, and the lens assembly for scanning terminals. It is explanatory drawing shown about the movement distance of the lens assembly for signal terminals which arranged the unit lens assembly in a line, and the lens assembly for scanning terminals. It is explanatory drawing shown about the movement distance of the lens assembly for signal terminals which arranged the unit lens assembly alternately, and the lens assembly for scanning terminals. It is a schematic plan view which shows the example which formed multiple types of mask patterns in one photomask, (a) shows the example of the photomask for signal terminals, (b) shows the example of the photomask for scanning terminals. .

  Embodiments of the present invention will be described below in detail with reference to the accompanying drawings. FIG. 1 is a front view showing an embodiment of an exposure apparatus according to the present invention, and FIG. 2 is a plan view of FIG. This exposure apparatus enables exposure of a non-periodic pattern on an object to be exposed having a large area with high resolution, and includes a conveying means 1, a first exposure optical unit 2, and a second exposure optical. Unit 3 is provided. In the following description, the case where the object to be exposed is a substrate for a thin film transistor (hereinafter referred to as “TFT”) of a display device will be described.

  FIG. 3 is a plan view of the TFT substrate 4 used in the present invention, in which exposure patterns of a plurality of signal lines and scanning lines intersect with each other in a predetermined cycle in the display area 5 by another exposure apparatus. It is a thing. An area 6 surrounded by a broken line in the figure outside the display area 5 is an area for forming a signal side terminal for connecting to a plurality of signal lines and a signal side driving circuit provided outside. Reference numeral 7 denotes an area for forming a scanning side terminal for connection to a plurality of scanning lines and a scanning side driving circuit provided outside.

  The transport means 1 is for placing the TFT substrate 4 coated with photosensitive resin on the upper surface of the stage 8 and transporting it in one direction (in the direction of arrow A shown in FIG. 1). The stage 8 is moved by a moving mechanism configured in combination. Alternatively, a gas outlet and suction port are provided on the surface of the stage 8, and the TFT substrate 4 is transported in a state where it floats on the stage 8 by a predetermined amount by balancing the gas jet output and suction force. May be. The transport unit 1 is provided with a position sensor (not shown) for detecting the moving distance of the stage 8.

  Above the transport means 1, a first exposure optical unit 2 is provided. The first exposure optical unit 2 is for exposing the pattern of the signal side terminal to the region 6 of the TFT substrate 4, and includes a light source device 9, a signal terminal photomask 10, and a signal terminal lens assembly. A solid 11 and a moving means 12 are provided.

  Here, the light source device 9 irradiates the signal terminal photomask 10 described later with the parallel light of the light source light having a uniform luminance distribution, for example, a light source composed of an ultra-high pressure mercury lamp, a xenon lamp or the like, The light source light emitted from the light source is configured to have a uniform luminance distribution, for example, a photo integrator, and a condenser lens that converts the light source light having the uniform luminance distribution into parallel light.

  A signal terminal photomask 10 is provided downstream of the light source light emitted from the light source device 9. As shown in FIG. 4, the signal terminal photomask 10 is formed by forming a signal terminal mask pattern 13 having the same shape as the signal terminal on the transparent substrate surface. It is held on a mask stage (not shown) with the surface facing down. The signal terminal photomask 10 is classified into a positive type and a negative type depending on the type of photosensitive resin used. Here, the case of the positive type will be described. Therefore, the signal terminal mask pattern 13 is formed of an opaque film, and light is transmitted through the outer region of the signal terminal mask pattern 13.

  A signal terminal lens assembly 11 is provided between the signal terminal photomask 10 and the stage 8 of the conveying means 1. The lens assembly 11 for signal terminals forms an equal-size erect image of the mask pattern 13 for signal terminals formed on the photomask 10 for signal terminals on the surface of the TFT substrate 4. In addition, it is formed so as to be movable in a direction parallel to the substrate conveying direction indicated by arrow A in FIG. 2 (in the direction of arrow B in FIG. 2) by a moving means 12 described later by a moving means 12 described later. The signal terminal unit lens assemblies 11A, 11B, and 11C are arranged in a line in a direction crossing the moving direction (arrow B direction).

  Here, in the signal terminal unit lens assemblies 11A to 11C, a plurality of convex lenses (microlenses) 14a to 14h are arranged in the normal direction of the signal terminal photomask 10 as shown in FIG. 6B. A plurality of lens rows 16 are arranged by arranging the lens groups 15 configured as described above in a plane parallel to the surfaces of the signal terminal photomask 10 and the stage 8 at a constant arrangement pitch in a direction crossing the moving direction (arrow B direction). As shown in FIG. 5, each lens group 15 of each lens array 16 is parallel to an axis OO that obliquely intersects the moving direction (arrow B direction) of the signal terminal lens assembly 11. The lens rows 16 are formed so as to be aligned with each other by a certain amount in the direction intersecting the arrow B direction, and the end portions 11Aa, 11Ba, 11Bb, and 11Ca adjacent to each other are formed on the axis O−. In which are arranged so as to be aligned in parallel to excised form the configurations, and constant arrangement pitch across the entire lens group 15 is a signal terminal for the lens assembly 11 of the lens array 16 in.

More specifically, as shown in FIG. 6A, the signal terminal unit lens assemblies 11 </ b> A to 11 </ b> C are plural in a direction orthogonal to the moving direction (arrow B direction) of the signal terminal lens assembly 11. the lens group 15 provided with a pitch _{P 1} (e.g. 150μm pitch) 3 rows of lens array 16 which are arranged at a pitch _{P 2} in the direction of movement indicated by the arrow B (e.g. 150μm pitch), in the moving direction (direction of arrow B) One lens row 16 of the adjacent lens rows 16 is arranged in the arrangement direction of the lens groups 15 so that a part of each lens group 15 of each lens row 16 overlaps when viewed, and the arrangement pitch P ₁ of the plurality of lens groups 15 is set. It is shifted by 1 / n (n is an integer of 2 or more and is indicated by n = 3 in FIG. 6).

  Each of the signal terminal unit lens assemblies 11A to 11C includes first, second, and second lens lenses 14 having a plurality of convex lenses 14 corresponding to the front and back surfaces of the transparent substrate 17, as shown in FIG. The third and fourth lens arrays 18a to 18d are overlapped and joined in a state where the optical axes of the corresponding convex lenses 14 are matched, and the intermediate inverted image of the signal terminal mask pattern 13 of the signal terminal photomask 10 is used. Is formed between the second lens array 18b and the third lens array 18c. In this case, the lens group 15 is composed of eight convex lenses 14a to 14h arranged with their optical axes aligned with each other.

  Here, the function of each convex lens 14 of the lens group 15 will be described. First, the front convex lens 14a of the first lens array 18a receives the principal ray of incident light in order to increase the amount of exposure light that has passed through the signal terminal photomask 10 into the lens group 15. This is a field lens that collects light on the surface of the rear convex lens 14b of 18a. In addition, the rear convex lens 14b of the first lens array 18a and the front convex lens 14c of the second lens array 18b cooperate to generate an image of the signal terminal mask pattern 13 of the signal terminal photomask 10 in the second. This is an imaging lens that serves to generate an intermediate inverted image of the signal terminal mask pattern 13 by forming an image between the lens array 18b and the third lens array 18c. Further, the rear convex lens 14d of the second lens array 18b is a field lens that serves to make the principal ray of incident light parallel to the optical axis. The front convex lens 14e of the third lens array 18c is a field lens that serves to collect the principal ray of incident light on the surface of the rear convex lens 14f of the third lens array 18c. Further, the rear convex lens 14f of the third lens array 18c and the front convex lens 14g of the fourth lens array 18d cooperate to form an intermediate inverted image of the signal terminal mask pattern 13 on the surface of the TFT substrate 4. This is an imaging lens that serves to generate an erect image of the signal terminal mask pattern 13 by imaging. The rear convex lens 14h of the fourth lens array 18d is a field lens that serves to make the principal ray of incident light parallel to the optical axis. As a result, the lens group 15 can form an equal-magnification erect image of the signal terminal mask pattern 13 of the signal terminal photomask 10 on the surface of the TFT substrate 4.

  Further, as shown in FIG. 6B, each of the signal terminal unit lens assemblies 11A to 11C includes a first opening 20 having a predetermined shape adjacent to the surface of the front convex lens 14e of the third lens array 18c. The aperture 19 is provided to limit the exposure area by the lens group 15 to the center of the lens. Thereby, it is possible to expose the signal terminal mask pattern 13 of the signal terminal photomask 10 with high resolution without the influence of lens aberration.

  In this case, as shown in FIG. 7, the opening 20 of the first diaphragm 19 is a rectangular opening having four corners 21a, 21b, 21c, and 21d, and the signal terminal lens assembly 11 is moved. The area of a portion corresponding to a portion (hereinafter referred to as “overlap portion 22”) overlapping with a part of the opening 20 of the first diaphragm 19 adjacent in the direction (arrow B direction) is the total area of the overlap portion 22. A part of the light is shielded so as to be half. In the present embodiment, as shown in FIG. 6A, the shape of the opening 20 of the first diaphragm 19 is a hexagon having a corner on the center line of the lens array 16. As a result, the area of the opening 20 of the first diaphragm 19 corresponding to the overlap portion 22 is half the total area of the overlap portion 22, and the average exposure amount of the region corresponding to the overlap portion 22 is required. Half of the exposure amount. Therefore, a region corresponding to the overlap portion 22 is subjected to a certain amount of exposure by overlapping exposure of the two lens groups 15 existing ahead of the moving direction (arrow B direction) of the signal terminal lens assembly 11. It will be. Therefore, there is no possibility that the area corresponding to the overlap portion 22 is overexposed.

Here, with reference to FIG. 8, a state where the region corresponding to the overlap portion 22 is exposed during the movement of the signal terminal lens assembly 11 will be described in more detail.
FIG. 8A is a plan view showing the lens group 15 existing ahead of the moving direction (arrow B direction) of the signal terminal lens assembly 11. FIG. 6B is an explanatory diagram showing exposure at a point O corresponding to the outside of the overlap portion 22 in FIG. In this case, the point O is limited by the aperture 20 of the first diaphragm 19, is exposed at the exposure from t ₁ is started t ₂ is completed. As a result, the point O is exposed to a certain amount of light during the period from t _{1 to} t ₂ , and exposure at a certain depth is performed.

On the other hand, FIG. 8C is an explanatory diagram showing exposure of a point P corresponding to the overlap portion 22. In this case, the point P is limited by the portion corresponding to the overlapping portion 22 of the opening 20 of the first diaphragm 19, after finishing exposure at t ₄ exposed from t ₃ is started once, the subsequent first is limited by the portion corresponding to the overlapping portion 22 of the aperture 20 of the diaphragm 19 exposed at t ₆ resumes the exposure from t ₅ of completed. Accordingly, the point P is exposed to light of constant light intensity in the _t 3 _{~t 4, t} 5 period ~t _6, so that the exposure of a predetermined depth is performed.

FIG. 8D is an explanatory diagram showing exposure at a point Q corresponding to the overlap portion 22. In this case, the point Q is limited by the portion corresponding to the overlap portion 22 of the opening 20 of the first aperture stop 19. After the exposure is started at t ₇ and the exposure is once ended at t ₈ , the subsequent first exposure in the overlap portion 22 is limited by a portion corresponding to resume the exposure from t ₉ t ₁₀ of the aperture 20 of the diaphragm 19 is completed. Accordingly, the point P is exposed to light of a predetermined light intensity in the period of the _{t 7 ~t 8, t 9 ~t} 10, so that the exposure of a predetermined depth is performed.

  Note that the shape of the opening 20 of the first diaphragm 19 is not limited to the hexagonal shape, and the shape of the portion corresponding to the overlap portion 22 of the opening 20 is half of the entire area of the overlap portion 22. As long as the portion is shielded from light, it may have any shape such as a trapezoid as shown in FIG.

  In addition, as shown in FIG. 6B, each of the signal terminal unit lens assemblies 11A to 11C is close to the surface of the convex lens 14g on the upstream side in the light traveling direction of the fourth lens array 18d. A second diaphragm 23 having an elliptical opening corresponding to the opening 20 of the diaphragm 19 is provided to limit the beam diameter of light passing through the lens group 15.

Further, each of the signal terminal unit lens assemblies 11A to 11C shields the periphery of the front convex lens 14a of the first lens array 18a and is outside the lens formation region sandwiched between two broken lines in FIG. The width w ₁ in the same direction of the region before and after the movement direction (in the direction opposite to the arrow A) indicated by the arrow B in FIG. It is formed to be the same as the width W _{1 in the} direction (see FIG. 4). Thus, the light passing through the signal terminal photomask 10 can be completely blocked before the signal terminal lens assembly 11 starts moving and after the movement is completed.

  A moving means 12 is provided to move the signal terminal lens assembly 11. The moving means 12 moves the signal terminal lens assembly 11 in a direction parallel to the signal terminal photomask 10 and the stage 8 in the direction of arrow B in FIG. is there.

  A second exposure optical unit 3 is provided above the stage 8 and in front of the first exposure optical unit 2 in the substrate transport direction. The second exposure optical unit 3 is for exposing the pattern of the scanning side terminal to the region 7 of the TFT substrate 4, and includes a light source device 23, a scanning terminal photomask 24, and a scanning terminal lens assembly. A solid body 25 and a moving means 26 are provided.

  Here, the light source device 23 irradiates a scanning terminal photomask 24 described later with parallel light of light source light having a uniform luminance distribution, and is similar to the light source device 9 of the first exposure optical unit 2. For example, a light source composed of an ultra-high pressure mercury lamp, a xenon lamp or the like, a luminance distribution of the light source light emitted from the light source, for example, a photo integrator, and a capacitor for converting the light source light with the uniform luminance distribution into parallel light And a lens.

  A scanning terminal photomask 24 is provided downstream of the light source light emitted from the light source device 23. As shown in FIG. 10, the scanning terminal photomask 24 is obtained by forming a scanning terminal mask pattern 27 having the same shape as the scanning terminal on the transparent substrate surface. It is held on a mask stage (not shown) with the surface facing down. The scanning terminal photomask 24 is classified into a positive type and a negative type depending on the type of photosensitive resin used, as in the case of the signal terminal mask pattern 13. Here, the case of the positive type will be described. . Therefore, the scanning terminal mask pattern 27 is formed of an opaque film, and light is transmitted through the outer region of the scanning terminal mask pattern 27.

  A scanning terminal lens assembly 25 is provided between the scanning terminal photomask 24 and the stage 8 of the conveying means 1. The scanning terminal lens assembly 25 forms an equal-magnification erect image of the scanning terminal mask pattern 27 formed on the scanning terminal photomask 24 on the surface of the TFT substrate 4. 2 is formed so as to be movable in the direction parallel to the substrate conveyance direction indicated by arrow A in FIG. 2 (in the direction of arrow C in FIG. 2) by a moving means 26 to be described later. A lens group 29 configured by arranging a plurality of convex lenses (microlenses) 28 a to 28 h in the normal direction as shown in FIG. A plurality of scanning terminal unit lens assemblies 25A, 25B, and 2 in which a plurality of lens arrays 30 are formed in a direction that intersects the moving direction (the direction of arrow C) at a constant arrangement pitch. The C are those having in a row in the crossing direction with the moving direction (arrow C direction) (see FIG. 2).

  Similarly to the signal terminal lens assembly 11 shown in FIG. 5, the scanning terminal unit lens assemblies 25 </ b> A to 25 </ b> C are configured such that each lens group 29 of each lens array 30 moves in the moving direction of the scanning terminal lens assembly 25. Each lens array 30 is formed by being shifted by a certain amount in the direction intersecting the arrow C so as to be arranged in parallel to an axis that obliquely intersects (in the direction of the arrow C), and adjacent end portions 25Aa, 25Ba, 25Bb, and 25Ca (see FIG. 2) are cut away in parallel to the axis, and the lens group 29 of each lens array 30 is arranged at a constant pitch over the entire scanning terminal lens assembly 25. They are arranged side by side.

More specifically, as shown in FIG. 11A, each of the scanning terminal lens assemblies 25A to 25C is in the moving direction of the scanning terminal lens assembly 25 (the direction of arrow C shown in FIG. 11). The lens rows 30 in which a plurality of lens groups 29 are arranged at a pitch P ₃ (for example, 150 μm pitch) in the direction intersecting with each other are provided in three rows at a pitch P ₄ (for example, 150 μm pitch) in the movement direction indicated by the arrow C, and the movement direction described above. A plurality of lens groups 29 are arranged in the arrangement direction of the lens groups 29 so that one of the lens groups 30 adjacent to each other so that a part of each lens group 29 of each lens array 30 overlaps when viewed in the direction of arrow C. 1 / m of the arrangement pitch P ₃ of the (m is an integer of 2 or more, indicated by m = 3 in FIG. 10) has a one provided by shifting.

  In addition, as shown in FIG. 11B, each of the scanning terminal lens assemblies 25A to 25C has first, second, and third lenses formed with a plurality of convex lenses 28 corresponding to the front and back surfaces of a transparent substrate. In addition, the fourth lens arrays 31a to 31d are superposed and joined in a state where the optical axes of the corresponding convex lenses 28 are matched, and an intermediate inverted image of the scanning terminal mask pattern 27 of the scanning terminal photomask 24 is formed. The second lens array 31b and the third lens array 31c are configured to form an image. In this case, the lens group 29 is composed of eight convex lenses 28a to 28h arranged with their optical axes aligned with each other. The configuration of the scanning terminal lens assembly 25 is the same as the configuration of the signal terminal unit lens assemblies 11A to 11C of the first exposure optical unit 2, and here, the specific configuration of the lens group 29 and Description of the function of each convex lens 28 is omitted. In FIG. 11, reference numeral 32 denotes a first diaphragm, reference numeral 33 denotes an opening of the first diaphragm 32, and reference numeral 34 denotes a second diaphragm.

Further, each of the scanning terminal lens assemblies 25A to 25C shields light from the periphery of the front convex lens 28a of the first lens array 31a and is outside the lens formation region sandwiched between two broken lines in FIG. The width W ₂ in the same direction of the region before and after the moving direction indicated by the arrow C in the figure is at least the width W _{2 in the} direction orthogonal to the arrow A of the scanning terminal mask pattern 27 formation region of the scanning terminal photomask 24 ( (See FIG. 10). Thus, the light passing through the scanning terminal photomask 24 can be completely blocked before the scanning terminal lens assembly 25 starts moving and after the movement is completed.

  A moving means 26 is provided to move the scanning terminal lens assembly 25. The moving means 26 moves the scanning terminal lens assembly 25 in a direction parallel to the scanning terminal photomask 24 and the stage 8 in the direction of arrow C in FIG. 2, for example, an electromagnetic actuator, an electric stage 8 or the like. It is.

Next, the operation of the exposure apparatus configured as described above will be described.
First, assembly adjustment is performed by an assembly adjustment device for a lens assembly provided separately so that the surface of each unit lens assembly is parallel to the substrate surface within an allowable value. The specific adjustment will be described with reference to FIG. Here, the assembly adjustment of the signal terminal lens assembly 11 will be described, and the assembly adjustment of the scanning terminal lens assembly 25 may be performed in the same manner, and the description thereof will be omitted.

First, a plurality of reference marks 35a, 35b ... a reference substrate 36 signal terminals lens assembly 11 on which is formed by arranging in a straight line at constant arrangement pitch P (an integral multiple of P ₁₎ is opposed. Next, the reference mark 35a is picked up by the microscope 37 through any one of the lens groups 15 of the signal terminal unit lens assembly 11A, and the signal terminal lens assembly 11 is moved in the horizontal plane so that the field of view of the microscope 37 is centered. The reference mark 35a is positioned at the position. Subsequently, the microscope 37 is horizontally moved in the arrangement direction of the reference marks 35a and 35b by the same dimension P as the arrangement pitch P of the reference marks 35a and 35b, and the microscope 37 is moved through the lens group 15 of the signal terminal unit lens assembly 11B. The th reference mark 35b is observed. Then, the signal terminal unit lens assembly 11B is moved in the direction of arrow D shown in FIG. 12, for example, so that the second reference mark 35b is positioned at the center of the field of view of the microscope 37, and then fixed. Thereafter, the signal terminal unit lens assembly 11C is similarly adjusted. Thus, the lens group 15 of the signal terminals lens assembly 11 will be aligned in a straight line in the direction array pitch P ₁ that intersects the movement direction indicated by the arrow B in FIG.

  The signal terminal lens assembly 11 and the scanning terminal lens assembly 25 assembled and adjusted as described above are set in the first exposure optical unit 2 and the second exposure optical unit 3, respectively. Thereby, exposure preparation is completed.

  Next, after the TFT substrate 4 on which the exposure patterns of the signal lines and the scanning lines are previously formed in the display area 5 is positioned and placed at a predetermined position on the stage 8 by another exposure apparatus, the conveying means 1 is driven. Then, the stage 8 is moved at a constant speed in the direction of arrow A in FIG. 1, and the TFT substrate 4 is conveyed in the same direction. At this time, the light sources of the first and second exposure optical units 2 and 3 are turned on.

  Subsequently, a reference mark (not shown) provided in advance on the TFT substrate 4 is detected by an imaging means (not shown) provided at a fixed distance from the first exposure optical unit 2 on the opposite side to the substrate transport direction. The moving distance of the stage 8 is measured by the position sensor with reference to the position of the stage 8 at the detection time of the reference mark. Then, when the stage 8 moves by a preset distance and the signal side terminal formation region 6 of the TFT substrate 4 reaches just below the signal terminal photomask 10 of the first exposure optical unit 2, the stage 8 moves. Stopped.

  Further, the moving means 12 of the first exposure optical unit 2 is driven to start the movement of the signal terminal lens assembly 11 in the arrow B direction in FIG. 1, and a plurality of lens groups continuously moving in the same direction. 15 (see FIG. 5), an equal-size erect image of the signal terminal mask pattern 13 of the signal terminal photomask 10 shown in FIG. 4 is projected onto the surface of the TFT substrate 4, and the exposure pattern of the signal side terminals is the TFT substrate. 4 in the signal side terminal formation region 6.

  At this time, as shown in FIG. 7, the area corresponding to the overlap portion 22 in the exposure area limited by the opening 20 of the first diaphragm 19 of the lens group 15 is for the signal terminal indicated by the arrow B in FIG. The two lens groups 15 existing ahead of the moving direction of the lens assembly 11 are overexposed. Thereby, the exposure pattern of the signal side terminal is continuously connected without being interrupted. In this case, the portion corresponding to the overlap portion 22 in the opening 20 of the first diaphragm 19 is formed so that the area thereof is half of the total area of the overlap portion 22. With this overexposure, exposure at a certain depth is performed, and there is no fear of overexposure.

  When the signal terminal lens assembly 11 is moved by a predetermined distance and the entire exposure pattern of the signal terminal mask pattern 13 is formed in the signal side terminal forming region 6 of the TFT substrate 4, the moving means 12 is stopped. The stage 8 starts to move and the conveyance of the TFT substrate 4 is resumed.

  Further, when the TFT substrate 4 moves by a certain distance and the scanning side terminal formation region 7 of the TFT substrate 4 reaches directly below the scanning terminal photomask 24 of the second exposure optical unit 3, the movement of the stage 8 is stopped. Is done.

  Subsequently, the moving means 26 of the second exposure optical unit 3 is driven to start the movement of the scanning terminal lens assembly 25 in the direction of arrow C in FIG. 2, and a plurality of lenses continuously moving in the same direction. The group 29 (see FIG. 11) projects an equal-magnification erect image of the scanning terminal mask pattern 27 of the scanning terminal photomask 24 shown in FIG. 10 onto the surface of the TFT substrate 4, and the scanning terminal exposure pattern is for TFT. It is formed in the scanning side terminal formation region 7 of the substrate 4.

  At this time, the region corresponding to the overlap portion in the exposure region limited by the opening 33 of the first diaphragm 32 of the lens group 29 is the lens assembly for signal terminals of the first exposure optical unit 2 shown in FIG. Similarly to the case of No. 11, the two exposures are performed by the two lens groups 29 existing ahead of the moving direction of the scanning terminal lens assembly 25 indicated by the arrow C in FIG. Thereby, the exposure pattern of the scanning terminal is continuously connected without being interrupted. In this case, the portion of the opening 33 of the first diaphragm 32 corresponding to the overlap portion has an area that is half the total area of the overlap portion, like the first diaphragm 19 of the first exposure optical unit 2. Therefore, exposure with a certain depth is performed by the overexposure of the two lens groups 29, and there is no fear of overexposure.

  When the scanning terminal lens assembly 25 moves by a certain distance and the entire exposure pattern of the scanning terminal mask pattern 27 is formed in the scanning side terminal formation region 7 of the TFT substrate 4, the moving means 26 stops. Then, all the exposure to the TFT substrate 4 is completed. Thereafter, the movement of the stage 8 is resumed and the TFT substrate 4 is discharged to the outside.

In the present invention, the signal terminal lens assembly 11 and the scanning terminal lens assembly 25 are each arranged with a plurality of signal terminal unit lens assemblies 11A to 11C and scanning terminal unit lens assemblies 25A to 25C arranged in a line. Therefore, the moving distance L ₁ of each of the lens assemblies 11 and 25 shown in FIG. 13 is the width W ₁ of the signal terminal mask pattern 13 formation region of the signal terminal photomask 10 in the arrow B direction. scanning the distance obtained by adding the arrow B direction of width of the lens forming region of the signal terminals lens assembly 11, and the width W ₂ of the arrow C direction of the mask pattern 27 forming region for the scanning pin of the scanning terminals photomask 24 The distance is the sum of the width of the lens formation region of the terminal lens assembly 25 in the direction of arrow C.

On the other hand, the signal terminal lens assembly 11 and the scanning terminal lens assembly 25 are configured by alternately arranging a plurality of signal terminal unit lens assemblies 11A to 11C and scanning terminal unit lens assemblies 25A to 25C. It may have. In this case, the moving distance L ₂ of each lens assembly 11, 25 shown in FIG. 14, an arrow B direction of the width W ₁ and the signal terminal unit lens of the mask pattern 13 forming region signal terminal of the photo signal terminal mask 10 The distance obtained by adding the width of the lens formation region of the assembly 11A and the signal terminal unit lens assembly 11B in the direction of arrow B, and the width of the scanning terminal mask pattern 27 formation region of the scanning terminal photomask 24 in the direction of arrow C becomes W ₂ to the distance the arrow C direction of width of the lens forming area of a scanning terminal unit lens assembly 25A and the scanning terminal unit lens assembly 25B obtained by adding the moving distance L of the lens assembly 11, 25 of the present invention ₁ (L ₁ <L ₂ ).

  In the above description, the case where one mask pattern is formed on one photomask has been described. However, the present invention is not limited to this, and as shown in FIG. May be formed. In this case, a desired mask pattern is selected by moving in the same direction as the moving direction of the photomask lens assembly. FIG. 15A shows the signal terminal photomask 10 and FIG. 15B shows the scanning terminal photomask 24.

  In the above embodiment, the case where the TFT substrate 4 is formed by the exposure pattern of a plurality of signal lines and scanning lines intersecting the display region 5 in the display area 5 by another exposure apparatus has been described. The present invention is not limited to this, and a first distance for forming the exposure pattern of the signal lines and the scanning lines on the TFT substrate 4 with a certain distance from the first exposure optical unit 2 on the opposite side to the substrate transport direction. Three exposure optical units may be provided. In this case, the third exposure optical unit includes two mask patterns composed of two types of mask patterns having different required resolving powers such as electrode wirings of thin film transistors, signal lines, and scanning lines on a light shielding film formed on one surface of the transparent substrate. A mask pattern group is formed ahead of the direction of transport of the TFT substrate 4, and the other surface corresponds to the mask pattern of the electrode wiring of the thin film transistor having a high required resolving power among the two types of mask patterns having different required resolving powers. A photomask formed with a microlens for reducing and projecting the mask pattern onto the TFT substrate 4 is arranged so that the microlens side is on the TFT substrate 4 side, and the light source light is fixed to the photomask. Two kinds of mask patterns of the photomask are applied to the TFT substrate 4 which is intermittently irradiated at time intervals and is transported at a constant speed in the direction of arrow A in FIG. Good those configured to expose the emissions at a constant period.

  The specific configuration example of the photomask used here is that the mask pattern group composed of the electrode wiring mask patterns of the thin film transistor having a high required resolving power is in the direction substantially orthogonal to the transport direction (arrow A direction) of the TFT substrate 4. A plurality of mask pattern rows formed by arranging the mask patterns in a straight line at a predetermined pitch, and the subsequent exposure patterns formed by the mask pattern rows positioned on the leading side in the transport direction of the TFT substrate 4 It is preferable that the subsequent mask pattern sequence is formed by shifting each of the mask patterns in the arrangement direction by a certain dimension so that the exposure pattern can be complemented by the plurality of exposure patterns formed by the mask pattern sequence.

  Furthermore, in the above-described embodiment, the case where the exposure is performed while moving the TFT substrate 4 in one direction has been described, but the present invention is not limited to this, and the TFT substrate 4 is exposed by moving the step in the two-dimensional plane. Also good.

  In the above description, the case where the object to be exposed is the TFT substrate 4 has been described. However, the present invention is not limited to this, and the object to be exposed is intended to form an aperiodic pattern. Anything may be used.

4 ... TFT substrate 8 ... Stage 10 ... Signal terminal photomask 11 ... Signal terminal lens assembly 11A to 11C ... Signal terminal unit lens assembly 11Aa, 11Ba, 11Bb, 11Ca ... Signal terminal unit lens assembly Adjacent end portion 13 ... Signal terminal mask pattern 14, 14a-14h, 28, 28a-28h ... Convex lens 15, 29 ... Lens group 16, 30 ... Lens array 17a, 31a ... First lens array 17b, 31b ... Second Lens array 17c, 31c ... Third lens array 17d, 31d ... Fourth lens array 19, 32 ... First stop 20, 33 ... Opening 22 ... Overlap (overlapping with the opening of the adjacent first stop) portion)
23, 34 ... second aperture 24 ... photomask for scanning terminal 25 ... lens assembly for scanning terminal 25A to 25C ... unit lens assembly for scanning terminal 25Aa, 15Ba, 15Bb, 25Ca ... of unit lens assembly for scanning terminal Adjacent end 27 ... Scanning terminal mask pattern

Claims (7)

The mask of the photomask is formed to be movable in a plane parallel to the surface of the object to be exposed and the surface of the photomask between a stage on which the object to be exposed is mounted and a photomask on which a mask pattern is formed. A plurality of unit lens groups in which a plurality of lens groups configured to form an equal-length erect image of a pattern on the surface of the object to be exposed are arranged at a constant arrangement pitch in a direction intersecting the moving direction, thereby forming a plurality of lens rows Comprising a lens assembly having solids arranged in a row in a direction intersecting with the moving direction,
Each unit lens assembly has a direction that intersects each lens array with the moving direction so that each lens group of each lens array is arranged in parallel with an axis that obliquely intersects the moving direction of the lens assembly. Are formed by shifting the end portions adjacent to each other in parallel to the axis, and the lens group of each lens array is constant over the entire lens assembly. An exposure apparatus characterized in that it is arranged so as to be arranged at an arrangement pitch of.   2. An exposure apparatus according to claim 1, wherein each of the unit lens assemblies is shifted from each other so that a part of each lens group overlaps when viewed in the moving direction of the lens assembly. .   Each of the unit lens assemblies has a first, second, third, and fourth lens array in which a plurality of convex lenses are formed corresponding to each other on the front and back surfaces of a transparent substrate so that the optical axes of the corresponding convex lenses coincide with each other. And an intermediate inverted image of the mask pattern of the photomask is formed between the second lens array and the third lens array. Item 3. The exposure apparatus according to Item 1 or 2.   Each of the unit lens assemblies is provided with a first aperture having a predetermined shape close to the surface of the convex lens located on the upstream side in the light traveling direction of the third lens array, and an exposure area by the lens group is provided. 4. The exposure apparatus according to claim 3, wherein the exposure apparatus is limited to a central portion of the lens.   In the opening of the first diaphragm, the area of the rectangular opening in plan view is such that the area of the part overlapping the part of the opening of the first diaphragm adjacent in the moving direction of the lens assembly is the area of the entire overlapping part. 5. An exposure apparatus according to claim 4, wherein a part of the light is shielded so as to be half of the exposure apparatus.   6. Each of the unit lens assemblies is provided with a second diaphragm that restricts a light beam diameter in the vicinity of the lens surface on the upstream side in the light traveling direction of the fourth lens array. The exposure apparatus according to any one of the above. The stage can transport the object to be exposed in one direction,
The lens assembly moves in a state where the movement of the stage is temporarily stopped;
The exposure apparatus according to any one of claims 1 to 6, wherein