JP2006189698A - Image reading apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To prevent the films from meandering and curling in the transfer path and remove dust on the film in an image reading apparatus. <P>SOLUTION: Two or more drum-like rollers are disposed with no drive source where to apply a certain pressure to the film in the film transfer path to correct the meandering and curling film, and an adhesive members are arranged on the whole surfaces of the drum-like rollers to remove the dust depositing on the film surface. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a film transport unit in an image reading apparatus such as a film.

  Conventionally, the film image reading apparatus sets the film to the positions of the film conveyance driven roller 7 and the film conveyance main driving roller 11 which are attached so as to be positioned at both ends of the film width as shown in FIG. The film conveyance driven rollers 7 to 10 suppress the film conveyance roller main movements 11 to 14 that are linked via a pressure plate 26 to a driving source (not shown) via a gear and the like, and a constant nip pressure is applied.

  The flow of the film image reading apparatus will be described below.

  In the first film conveyance, when the film is set to the position of the film conveyance driven roller 7 and the film conveyance main driving roller 11, the sensor 20 detects the film, and a drive (not shown) is driven by a control unit incorporated in the apparatus (not shown). A film transport main driving roller 11 interlocked with the source via a gear or the like rotates in the film transport forward direction, and transports the film by friction with the film transport driven roller 7 to which a constant nip pressure is applied. When the sensor 21 detects the film, the film transport rollers 8 to 10 and 12 to 14 transport the film in the same manner as the film transport driven roller 7 and the film transport main drive roller 11 to record information on the film for three frames. At this point, only the film information for three frames is recorded, so when recording is finished, the film is controlled to return to the state before the sensor 21 and to the state where it is caught by the film transport driven roller 7 and the film transport roller 11. Has been.

  In the second film transport, a start operation is performed by software from an externally connected PC (not shown) to read rough image information on the film. When the start operation is performed, similarly to the first film transport method, when the sensor 21 is passed, the film transport rollers 8 to 10 and 12 to 14 automatically start axis rotation according to the command of the control unit, Transport. The film that has passed through the film transport driven roller 10 and the film transport main drive roller 14 is stored in a film storage chamber 22 in a roll. The image information of the film emits visible light by the lamp 15 and infrared light by the infrared LED 16 and reflects to the mirror 23. Visible light is reflected by the infrared transmission mirror 24 and image information is recognized by the CCD 17, and infrared light passes through the infrared transmission mirror 24 and image information is recognized by the CCD 18.

  After recognizing the image information of all the frames, the film stored in the film storage chamber 22 by winding up is returned by the reversing operation of the film transport roller. In the process of returning the film by the reversing operation of the film transport roller, fine image information of all frames is recognized by the same image information recognition method as described above.

As another conventional example, for example, Patent Document 1, Patent Document 2, and Patent Document 3 can be cited.
Japanese Patent Laid-Open No. 10-023195 JP 10-133295 A JP 2002-296690 A

  However, in the above prior art example, only the film transport rollers 7 to 14 attached so as to be positioned at both ends of the film width curl the film as shown in FIG. Nip pressure is applied to the film transport rollers 7 to 14 that have given a constant nip pressure due to a feeding error caused by contact with other parts or a slight deviation of the film position that occurs during film feeding. There was a problem that a difference occurred and meandering occurred. Furthermore, since this apparatus reads image information with the film set in a substantially horizontal direction instead of reading the image information with the film set in a substantially vertical direction, there is a problem that dust floating in the air tends to adhere to the film. there were.

  As a means for solving the above-described problems, the image reading apparatus of the present invention applies the principle that when a certain pressure is applied to the approximate center of the width of the film, the curl in the film transport direction is corrected and straightened, and the film is image information. Before passing the position where the film is read, a drum-shaped roller that does not have a drive source and can rotate in the forward and reverse directions of the film is positioned at a height that can correct the curl of the film, and the film is centered on the center of the film. The curl of the film is corrected by pressing substantially the entire width downward. Furthermore, when the circumference of the drum-shaped roller increases as it approaches the center, since the peripheral speed of the central portion increases, the film is drawn to the faster peripheral speed by utilizing the well-known law, The meandering of the left and right sides of the film can also be prevented. Furthermore, the sticky material is arranged on the surface of the drum-shaped roller to remove dust attached to the film.

  As described above, an image reading apparatus such as a film according to claim 1 of the present invention includes a rotatable drum-shaped roller that does not have one or a plurality of driving sources in the film conveyance path of the image reading apparatus. By providing it at the approximate center of the width of the transport path of film, etc., and at a position where a certain force can be applied to the film, etc. in the direction perpendicular to the transport path, the supply that occurs when the film curls and comes into contact with other parts. It is possible to prevent meandering caused by a difference in nip pressure generated in a film transport roller that has given a constant nip pressure due to a feeding error or a slight shift of the film position that occurs during film feeding.

  According to the present invention, the image reading device such as a film according to claim 2, wherein the drum-shaped roller has a width substantially equal to the width of the film, and the adhesive member is disposed on the entire surface of the drum-shaped roller. In addition to preventing the feeding error and the meandering, dust adhering to the film can be removed.

1.
FIG. 1 is an external view showing an image reading apparatus such as a film scanner to which a drum-shaped roller coated with a material having adhesiveness is applied to the entire outer peripheral surface without a drive source according to the present invention. A cross-sectional view parallel to the forward / reverse direction of the road is shown in FIG. The outer lid 1 is capable of rotating the substantially rear end of the lower unit 2 about an axis perpendicular to the film conveyance normal / reverse direction. When reading the film 3, the outer lid 1 is kept closed by the lock of the lever 4 as shown in FIG. When the exterior lid 1 is closed as shown in FIG. 2, the film transport driven roller 7 and the film transport main roller 11, the film transport driven roller 8 and the film transport main roller 12, the film transport driven roller 9 and the film transport main drive, respectively. A certain nip pressure is applied to the roller 13, the film transport driven roller 10 and the film transport main drive roller 14. This structure is the same on the exterior lid 5 and the lever 6 side.

  In an image reading apparatus such as a film scanner to which a drum-shaped roller 19 coated with a material having adhesiveness is applied to the entire outer peripheral surface without a drive source according to the present invention, the image information of the film includes lamp 15 Since visible light, infrared LED16 emits infrared light and is read by CCD17 and CCD18, it is important that there is no curling or meandering of the film when passing under lamp 15 and infrared LED16. , Before the lamp 15 and the infrared LED 16, here, at a position before the film transport driven roller 7 and the film transport main drive roller 11.

  Next, FIG. 3 is a perspective view of the structure in which the film is transported by the film transport roller after the dust is removed by the rotatable drum-shaped roller having no driving source of the present invention, curling and meandering are corrected. Show. The drum-shaped roller 19 is installed at a position before the starting point of the film transport roller, and at a height where the center of the film width and the center of the roller width are substantially matched to correct the curl of the film. By doing so, when setting the film to the position of the film transport driven roller 7 and the film transport main driving roller 11 attached to the position of the film width, the drum-shaped roller 19 is moved by moving the film in the forward transport direction. The film rotates in the forward direction of the film conveyance by friction with the film, and the curl of the film is corrected. Furthermore, the meandering of the film is prevented by using the principle that the film converges in the center direction of the drum-shaped roller due to the difference in peripheral speed due to the difference in the circumference of the drum-shaped roller. Furthermore, if a sticky material is disposed on the surface of the drum-shaped roller, it can be attached to the positions of the film transport driven roller 7 and the film transport main drive roller 11 with the dust on the film surface removed.

  FIG. 4 shows a cross section perpendicular to the conveyance forward / reverse direction of the conveyance path and before the installation position of the drum-shaped roller 19, and also perpendicular to the conveyance normal / reverse direction of the conveyance path and of the installation position of the drum-shaped roller 19 Fig. 5 shows a cross section, and Fig. 6 shows a cross section of the installation position of the film conveyance driven roller 7 and the film conveyance main driving roller 11 in the same direction perpendicular to the conveyance normal / reverse direction of the conveyance path. Details of the height to correct.

  As shown in FIG. 4, the film 3 before passing through the drum roller 19 is curled upward. In order to correct the curl of the film 3 and bring it closer to the dotted line 3-1 and to remove dust adhering to the film surface, the maximum light part of the drum-shaped roller 19 has a dotted line on the surface in contact with the film 3 It is necessary to install it below the line 3-1. If the drum-shaped roller 19 is installed at such a position, as shown in FIG. 5, when the film 3 passes the drum-shaped roller 19, a force pressed from above by the drum-shaped roller 19 is applied to the film 3. By doing so, when the film 3 is conveyed by the film conveyance driven roller 7 and the film conveyance main driving roller 11 as shown in FIG. 6, the surface of the film 3 is in a state where the curl is corrected and is close to the dotted line 3-1 become.

  As shown in FIG. 2, in the first film transport of the image reading apparatus, such as a film scanner having a rotatable drum-like roller 19 that does not have a driving source according to the present invention installed at the above position, a drum-like roller is used. The film set up to the position of the film transport driven roller 7 and the film transport main roller 11 while curling is corrected by 19 and preventing meandering is detected by the sensor 20, and a control unit incorporated in the apparatus (not shown) Thus, the film conveyance main driving roller 11 rotates in the film conveyance positive direction, and is conveyed by friction with the film conveyance driven roller 7 to which a certain nip pressure is applied. When the sensor 21 detects the film, the film transport rollers 8 to 10 and 12 to 14 transport the film in the same manner as the film transport roller 7 and the film transport main driving roller 11, and record film information such as barcodes for three frames. To do. At this time, only the information of the film for three frames is recorded, so when the recording is finished, the film returns to a state before the sensor 21 and to the state where it is caught by the film transport driven roller 7 and the film transport main roller 11. Is controlled.

  In the second film transport of the image reading apparatus, such as a film scanner having a rotatable drum-shaped roller 19 that does not have a driving source of the present invention installed at the above position, from an externally connected PC not shown in the figure. Start operation in software, and read the rough image information of the film. When the start operation is performed, as in the first film transport method, the film transport rollers 8 to 10 and 12 to 14 automatically start rotating when the sensor 21 is passed to transport the film. The film that has passed through the film transport driven roller 10 and the film transport main drive roller 14 is wound around the film storage chamber 22 and stored. The image information of the film emits visible light by the lamp 15 and infrared light by the infrared LED 16 and reflects to the mirror 23. Visible light is reflected by the infrared transmission mirror 24 and image information is recognized by the CCD 17, and infrared light passes through the infrared transmission mirror 24 and image information is recognized by the CCD 18.

2.
In the embodiment described above, it is an example in the case of reading image information only in the film transport forward direction, and in the case of a structure that reads the image information even in the process of returning the film by the reversing operation of the film transport roller, The role of the drum-shaped roller having no driving source of the present invention is not so much played. Therefore, in addition to the drum roller 19, a structure in which the drum roller 25 is installed at a position after the end point of the film transport roller will be described.

  FIG. 7 shows a cross-sectional view parallel to the forward and reverse direction of conveyance of an image reading apparatus such as a film scanner, in which a drum-shaped roller 25 is installed at a position after the end point of the film conveyance roller, in addition to the drum-shaped roller 19.

  As shown in FIG. 7, the drum-shaped roller 19 is positioned in front of the starting point of the film transport roller, and the center of the film width and the center of the roller width substantially coincide with each other as described in the first embodiment. Install at a height that can correct By doing so, when setting the film to the position of the film transport driven roller 7 and the film transport main driving roller 11 attached to the position of the film width, the drum-shaped roller 19 is moved by moving the film in the forward transport direction. The film rotates in the forward direction of the film by friction with the film and the curl of the film is corrected, and the difference in the peripheral speed due to the difference in the circumference of the drum-shaped roller causes the film to move in the direction with the larger peripheral speed, that is, in the center direction By converging, the film can be prevented from meandering, and can be attached to the position of the film transport driven roller 7 and the film transport main drive roller 11 with the dust removed by the adhesive material arranged on the surface of the drum-shaped roller. .

  As with the drum-shaped roller 19, the drum-shaped roller 25 is positioned behind the end point of the film transport roller, and the height of the film width and the center of the roller width substantially coincide to correct the curl of the film. Install in. By doing so, the drum-shaped roller 25 plays the same role as the drum-shaped roller 19 in the structural process of reading image information when the film 3 wound around the film storage chamber 22 returns by the reversing operation of the film transport roller. Fulfill.

  Further, the drum-shaped roller 25 also plays a role of assisting the role of the drum-shaped roller 19 in the film transport forward direction.

  In the first film conveyance, the curl is corrected by the drum-shaped roller 19 and the film set up to the position of the film conveyance driven roller 7 and the film conveyance main driving roller 11 is detected by the sensor 20 and incorporated in the apparatus (not shown). By the control unit, the film conveyance main driving roller 11 rotates in the film conveyance positive direction and is conveyed by friction with the film conveyance driven roller 7 to which a certain nip pressure is applied. When the sensor 21 detects the film, the film transport rollers 8 to 10 and 12 to 14 transport the film in the same manner as the film transport roller 7 and the film transport main driving roller 11, and record film information such as a barcode for three frames. . At this time, only the film information for three frames is recorded, so when the recording is completed, the film returns to the state before the sensor 21 and to the state where it is caught by the film transport driven roller 7 and the film transport main roller 11. It is controlled.

  In the second film transport, a start operation is performed by software from an externally connected PC (not shown) to read rough image information on the film. When the start operation is performed, as in the first film transport method, the film transport rollers 8 to 10 and 12 to 14 automatically start rotating when the sensor 21 is passed to transport the film. The film that has passed through the film transport driven roller 10 and the film transport main drive roller 14 is stored in a film storage chamber 22 in a roll. The image information of the film emits visible light by the lamp 15 and infrared light by the infrared LED 16 and reflects to the mirror 23. Visible light is reflected by the infrared transmission mirror 24 and image information is recognized by the CCD 17, and infrared light passes through the infrared transmission mirror 24 and image information is recognized by the CCD 18.

  After recognizing the image information of all the frames, the film that has been wound and stored in the film storage chamber 22 is returned by the reversing operation of the film transport roller. In the process of returning the film by the reversing operation of the film transport roller, as with the drum roller 19, the position after the end point of the film transport roller, and the center of the film width and the center of the roller width match, The drum-shaped roller 25 installed at a height that can correct the curl of the film functions in the same manner as the drum-shaped roller 19. Then, fine image information of all frames is recognized by the same image information recognition method as described above.

  In Embodiment 2, as shown in FIG. 7, in addition to the drum-shaped roller 19 installed at a position before the start point of the film transport roller, the drum-shaped roller 25 is disposed at a position after the end point of the film transport roller. Although the structure of an installed image reading device such as a film scanner is mentioned, it is needless to say that a plurality of drum-shaped rollers may be provided according to the length of the film transport distance.

1 is an external view of an image reading apparatus according to the present invention. It is a cross-sectional perspective view of an image reading mechanism in the image reading apparatus of the present invention. It is a perspective view of the film conveyance structure in the image reading apparatus of this invention. It is a drum roller installation position explanatory state diagram in the image reading apparatus of the present invention. FIG. 5 is a cross-sectional view of the image reading apparatus of the present invention viewed from the front of FIG. It is sectional drawing which looked at the film conveyance roller part from the front which shows the normal conveyance state of the film in the image reading apparatus of this invention. It is a perspective view of the section of the film conveyance structure which installed two drum-like rollers in the present invention. It is a perspective view of a section of an image reading mechanism in a conventional example. FIG. 9 is a transport failure state diagram in FIG.

Explanation of symbols

1 Exterior lid
2 Lower unit
3 film
4 Lever
5 Exterior lid
6 Lever
7 Film transport driven roller
8 Film transport driven roller
9 Film transport driven roller
10 Film transport driven roller
11 Film transport main roller
12 Film transport main roller
13 Film transport main roller
14 Film transport main roller
15 Lamp
16 Infrared LED
17 CCD
18 CCD
19 drum roller
20 sensors
21 sensors
22 Film storage room
23 Mirror
24 Infrared transmission mirror
25 drum roller
26 Pressure plate

Claims (2)

  In an image reading apparatus such as a film, in which an exterior lid is configured to be openable and closable with respect to a main body having a conveyance driving unit such as a film, a rotatable drum-shaped roller having no one or a plurality of driving sources Is installed at a position in the vertical direction at which a constant force can be applied to the film or the like in a direction substantially perpendicular to the conveyance path and in a direction perpendicular to the conveyance path.   2. The image reading apparatus according to claim 1, wherein a member having adhesiveness is arranged on the entire surface of the drum-shaped roller, wherein the width of the drum-shaped roller is substantially equal to the width of the film or the like.

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