JP3928550B2 - Photosensitive media transport device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
  The present invention relates to a photosensitive medium conveyance device for conveying a photosensitive medium.
[0002]
[Prior art]
  The photographic processing apparatus includes an exposure stage that supports photographic paper on which printing exposure is performed, an information recording apparatus that records cut marks and the like disposed on the downstream side of the exposure stage, and an advance that sends out photographic paper from the exposure stage. Some include a transfer device including a path length changing device (dancer mechanism) disposed between the roller and the exposure stage and the advance roller (see, for example, Patent Document 1). In such a photographic printing processing apparatus, by changing the paper transfer path length in the path length changing device, the photographic paper is transported on the upstream side of the path length changing apparatus and the photographic paper on the downstream side of the path length changing apparatus. The conveyance can be separated. Therefore, in such a photographic printing processing apparatus, even when the size of the print screen to be printed on the exposure stage is changed, the printing exposure operation on the exposure stage and the recording of the print information by the information recording apparatus are simultaneously performed. be able to. Therefore, print information can be recorded during printing exposure regardless of the print size.
[0003]
  Here, the path length changing device includes an advance roller, a guide roller, a dancer roller for guiding the movement of the photographic paper between the advance roller and the guide roller, and the dancer roller in a direction intersecting the transfer direction of the photographic paper. And a roller moving mechanism for moving in the (vertical direction). The dancer roller is rotatably supported by a roller shaft attached to a support member that can move in the vertical direction. Therefore, in the path length changing device, the paper transfer path length can be changed by moving the dancer roller in the vertical direction by moving the support member in the vertical direction by the roller moving mechanism.
[0004]
[Patent Document 1]
      JP-A-6-347908 (FIG. 1)
[0005]
[Problems to be solved by the invention]
  However, in the above-described path length changing device, the dancer roller is attached to the support member so as not to move in the moving direction thereof, and therefore, for example, the outer diameter of the dancer roller becomes constant in the axial direction due to a manufacturing error or the like. If the dancer roller is not attached horizontally, a gap may be formed between the outer peripheral surface of the dancer roller and the photographic paper in contact with the dancer roller. In this case, it becomes impossible to apply a force evenly in the width direction to the photographic paper from the dancer roller, causing a problem that the photographic paper is twisted or meandered.
[0006]
  SUMMARY OF THE INVENTION Accordingly, an object of the present invention is to allow conveyance of the photosensitive medium while changing the length of the photosensitive medium between the first roller pair and the second roller pair. It is an object of the present invention to provide a photosensitive medium transport device capable of applying a force.
[0007]
[Means for Solving the Problems]
  In order to achieve the above object, a photosensitive medium transporting apparatus according to claim 1 includes a first roller pair that sandwiches a long photosensitive medium and transports it downstream, and a downstream side of the first roller pair. A second roller pair that sandwiches the photosensitive medium and conveys the photosensitive medium further downstream, and abuts against the photosensitive medium between the first roller pair and the second roller pair, and The photosensitive medium is movable in a direction in which the length of the photosensitive medium between the roller pair and the second roller pair changes, and the photosensitive medium between the first roller pair and the second roller pair A contact member biased in the direction of increasing the length, and both ends of the contact member in the width direction of the photosensitive mediumThe photosensitive member and the outer peripheral surface of the contact member So that no gap is formed between the media.Can be displaced freelyKeepHoldingAnd can move with the abutting member along a shaft fitted in the through hole.And a holding member.
[0008]
  According to the first aspect of the present invention, the contact members biased in the direction of increasing the length of the photosensitive medium between the first roller pair and the second roller pair are the first roller pair and the second roller. When moving in the direction in which the length of the photosensitive medium between the pair changes, both ends of the contact member areDo not create a gap between the outer peripheral surface of the contact member and the photosensitive mediumSince it is held by the holding member so as to be freely displaceable, a force from the contact member can be uniformly applied to the photosensitive medium in the width direction. Therefore, the length of the photosensitive medium between the first roller pair and the second roller pair can be controlled more accurately by controlling the first roller pair and the second roller pair, respectively. At the same time, the photosensitive medium is less likely to twist or meander due to the fact that an equal force is not applied from the contact member to the photosensitive medium.
  In addition, for example, the abutting member can be stably held by the holding member as compared with a case where the abutting member is held while the moving path is regulated by the holding member that does not move with the abutting member.
[0009]
  According to a second aspect of the present invention, the contact member is a roller that is held by the holding member so as to be rotatable about an axis.
[0010]
  According to the second aspect, the contact member can easily roll with respect to the photosensitive medium, and the damage of the photosensitive medium due to the contact member contacting the photosensitive medium can be suppressed. This is particularly effective when the contact member contacts the photosensitive surface of the photosensitive medium.
[0011]
[0012]
[0013]
  Claims3The photosensitive medium conveying apparatus further includes position detecting means for detecting the position of the contact member.
[0014]
  Claim3According to this, the first and second roller pairs can be controlled so that the length of the photosensitive medium between the first roller pair and the second roller pair is always equal to or greater than a certain value. The conveyance of the photosensitive medium by the roller pair can be separated from the conveyance of the photosensitive medium by the first roller pair.
[0015]
  Claims4The photosensitive medium conveying apparatus includes a plurality of sensors in which the position detecting unit is arranged to be separated from each other along a moving direction of the contact member, and the interval between the plurality of sensors and the contact member or the Holding memberTransferThe length along the moving direction is always determined by some of the plurality of sensors.The contact member or the holding memberIt is characterized in that the relation is set such that is detected.
[0016]
  Claim4According to this, the position of the contact member can always be grasped by the sensor.
[0017]
  Claims5The photosensitive medium transport device is perpendicular to the moving direction of the contact member.NaHas a surfaceandWith the abutment memberMoved toMovableThe leading edge of the photosensitive medium is guided from the first roller pair to the second roller pair.A guide member is further provided.
[0018]
  Claim5According to the above, when the front end portion of the photosensitive medium is conveyed between the first roller pair and the second roller pair disposed on the downstream side of the contact member, the front end portion of the photosensitive medium is moved to the first roller. It is possible to reliably guide the pair until reaching the second roller pair.
[0019]
  Claims6In the photosensitive medium transporting apparatus, the holding member includes a first holding member and a second holding member for holding the contact member at each of both end portions in the width direction of the photosensitive medium. At least one of the first holding member and the second holding member can be displaced in the width direction of the photosensitive medium.
[0020]
  Claim6According to the present invention, when the first holding member and the second holding member move together with the contact member while maintaining a constant distance therebetween, even if the contact member is largely inclined in the axial direction, It can be suppressed that the first holding member and the second holding member cannot move.
[0021]
  Claims7The photosensitive medium transport device contacts the abutting member that moves beyond a predetermined position in the direction of increasing the length of the photosensitive medium between the first roller pair and the second roller pair. Further, a cushion member that gradually reduces the moving speed is further provided.
[0022]
  Claim7According to the present invention, when the rear end portion of the photosensitive medium passes between the first roller pair and the second roller pair, or at a position other than between the first roller pair and the second roller pair. Even when the force applied to the contact member from the photosensitive medium between the first roller pair and the second roller pair is smaller than the urging force against the contact member by cutting The abutting member collides with a member provided in the moving direction at a high speed by moving according to the biasing force in the direction of increasing the length of the photosensitive medium between the first roller pair and the second roller pair. Can be suppressed. Therefore, the contact member or its peripheral members can be prevented from being damaged.
[0023]
  Claims8The photosensitive medium transport device includes a rear end detection sensor for detecting a rear end portion of the photosensitive medium upstream of the first roller pair, and the rear end detection sensor detects the rear end portion of the photosensitive medium. Thereafter, the movement prohibiting means for prohibiting the contact member from moving beyond a predetermined position in the direction of increasing the length of the photosensitive medium between the first roller pair and the second roller pair. And is further provided.
[0024]
  Claim8According to the present invention, when the rear end portion of the photosensitive medium passes between the first roller pair and the second roller pair, or at a position other than between the first roller pair and the second roller pair. Even when the force applied to the contact member from the photosensitive medium between the first roller pair and the second roller pair is smaller than the urging force against the contact member by cutting The abutting member collides with a member provided in the moving direction at a high speed by moving according to the biasing force in the direction of increasing the length of the photosensitive medium between the first roller pair and the second roller pair. Can be suppressed. Therefore, the contact member or its peripheral members can be prevented from being damaged.
[0025]
DETAILED DESCRIPTION OF THE INVENTION
  Hereinafter, preferred embodiments of the present invention will be described with reference to the drawings. FIG. 1 is a view showing a schematic configuration of an exposure apparatus including a transport apparatus according to an embodiment of the present invention. FIG. 2 is a front view illustrating a schematic configuration of the adapter unit.
[0026]
  As shown in FIG. 1, an exposure apparatus 1 including a transport apparatus according to the present embodiment exposes photographic paper 2 with laser light to form a latent image on the photographic paper 2 in a casing 7. A unit 70 and a transport device 8 that transports the photographic paper 2 so as to face the exposure unit 70 are provided. Further, the paper magazine 6 and the winding unit 100 can be attached to and detached from the housing 7. Therefore, in the exposure apparatus 1, the photographic paper 2 drawn out from the paper magazine 6 is transported to the exposure unit 70 along the transport path by the transport device 8, exposed, and then transported toward the winding unit 100. Is done.
[0027]
  Here, in the following description, the normal conveyance direction of the photographic paper 2 by the conveyance device 8 is the direction from the paper magazine 6 to the exposure unit 70 and further from the exposure unit 70 to the take-up unit 100. Based on the direction, the upstream side in the transport direction of the photographic paper 2 (hereinafter simply referred to as “upstream side”) and the downstream side in the transport direction of the photographic paper 2 (hereinafter sometimes simply referred to as “downstream side”). I will express it. Accordingly, the paper magazine 6 can be attached to and detached from the casing 7 at a position corresponding to the most upstream side of the transport apparatus 8, while the winding unit 100 is positioned at a position corresponding to the most downstream side of the transport apparatus 8. Detachable.
[0028]
<Configuration of Paper Magazine 6 and Winding Unit 100>
  The paper magazine 6 has a light-shielding casing 5 in which a discharge port 5a is formed, and stores a wound body 2a in which a long unexposed photographic printing paper 2 is wound in a roll shape. Here, the wound body 2 a is supported in the housing 5 so as to be rotatable around the shaft 3. The photographic paper 2 unwound from the wound body 2a is guided by the guide roller 4 and discharged into the exposure apparatus 1 from the discharge port 5a. On the other hand, the winding unit 100 has a light-shielding casing 101 in which an insertion port 101a is formed, and the exposed photographic paper 2 exposed by the exposure apparatus 1 is inserted from the insertion port 101a in order from the leading end. The wound body 2a ′ is formed by being inserted and wound around the shaft 102.
[0029]
  Here, in the present embodiment, the photographic paper 2 wound around the wound body 2a housed in one paper magazine 6 is appropriately replaced with the winding unit 100 mounted on the housing 7. A case where a plurality of winding bodies 2a ′ are formed by being separately wound around a plurality of winding units 100 is shown, and the maximum diameter of the winding body 2a ′ that can be stored in the winding unit 100 is the paper magazine. 6 is smaller than the maximum diameter of the wound body 2a that can be accommodated in the inside. The take-up unit 100 for storing the wound body 2a ′ of the exposed photographic paper 2 is attached to a processor (not shown), which is a separate development processing apparatus, after being removed from the exposure apparatus 1, and exposed. The developed photographic paper 2 is developed.
[0030]
<Overall configuration of transport device 8>
  The conveyance device 8 includes an adapter unit 10, a conveyance roller pair 20, a dancer unit 30, which are arranged in order from the upstream side to the downstream side between the paper magazine 6 mounted on the housing 7 and the exposure unit 70. The conveyance roller pair 21, the image information adding unit 50, the conveyance roller pair 24 and the pressure roller pair 25 disposed so as to face the exposure unit 70, and the conveyance roller pair 26 disposed on the downstream side of the exposure unit 70. have. A first slack section 60 is formed between the image information adding section 50 and the transport roller pair 24, and a second slack section 80 is formed between the pressure roller pair 25 and the transport roller pair 26. ing.
[0031]
<Configuration of adapter unit 10>
  The adapter unit 10 is disposed on the most upstream side of the transport path of the transport device 8 and is a portion where the paper magazine 6 is mounted. Here, in the adapter unit 10, as shown in FIGS. 1 and 2, the photographic paper 2 drawn out from the paper magazine 6 is inserted in the vicinity of the lower end of the adapter unit 10, and then the adapter unit 10 is moved upward from below. It is conveyed toward. The adapter unit 10 includes a conveyance roller pair 15 and a dancer mechanism 16. The conveyance roller pair 15 is disposed in the vicinity of the upper end portion of the adapter unit 10, and sandwiches the photographic paper 2 drawn out from the paper magazine 6 and conveys it downstream from the adapter unit 10. .
[0032]
  Here, the conveyance roller pair 15 is connected to a motor 15a (see FIG. 10) for driving the rotation thereof, and the rotation speed (number of rotations) of the motor 15a is controlled by the controller 200 (see FIG. 10). . Accordingly, the transport speed (feeding speed) of the photographic paper 2 by the transport roller pair 15 can be adjusted as appropriate by the controller 200. The conveyance roller pair 15 applies a conveyance force to the photographic paper 2 mainly until the photographic paper 2 is sandwiched between the conveyance roller pair 20.
[0033]
  As shown in FIGS. 1 and 2, the dancer mechanism 16 has a guide roller 11 disposed in the vicinity of the lower end of the adapter unit 10 (in the vicinity of the discharge port 5a of the housing 5 of the paper magazine 6 attached to the housing 7). A guide roller 13 disposed above the guide roller 11 at a predetermined interval, a dancer roller 12 disposed between the guide roller 11 and the guide roller 13, and a guide roller 13 and a conveying roller pair 15. And a guide roller 14 disposed therebetween. The guide rollers 11, 13, and 14 are for guiding the photographic paper 2 drawn out from the paper magazine 6 to the conveying roller pair 15, and are all provided so as to be rotatable around their axes.
[0034]
  The dancer roller 12 is capable of moving in a direction in which the length of the photographic paper 2 changes between the guide roller 11 and the guide roller 13 by contacting the photographic paper 2 between the guide roller 11 and the guide roller 13. In this case, the length of the photographic paper 2 between the guide roller 11 and the guide roller 13 is urged in the direction of increasing.
[0035]
  Specifically, the dancer roller 12 is rotatably supported by one end portion of the support member 12 a, and the other end portion of the support member 12 a is rotatably supported by the rotation shaft 13 a of the guide roller 13. The dancer roller 12 has a position of almost the same horizontal height as the guide roller 13 (indicated by a two-dot chain line in FIG. 1 and hereinafter referred to as “original position”), the guide roller 11, the guide roller 13, The photographic paper 2 between the two is swayed with the rotary shaft 13a as a fulcrum between the position when the photographic paper 2 is conveyed without being curved (indicated by the alternate long and short dash line in FIG. It is provided to be movable.
[0036]
  Here, a torsion spring (not shown) is disposed between the support member 12a that supports the dancer roller 12 and the rotary shaft 13a. Therefore, the dancer roller 12 is always urged in the direction from the maximum swing position to the original position (the direction in which the length of the photographic paper 2 between the guide roller 11 and the guide roller 13 is increased). Accordingly, when the photographic paper 2 is not conveyed through the adapter unit 10, the dancer roller 12 is disposed at the original position. In addition, the structure for urging the dancer roller 12 in the above direction is not limited to that using a torsion spring, and any structure that can apply a urging force in the above direction to the dancer roller 12 may be used. .
[0037]
  Further, when the photographic paper 2 is conveyed in the adapter unit 10, the dancer roller 12 is based on the force received from the photographic paper 2 conveyed between the guide roller 11 and the guide roller 13. Swings from its original position toward the maximum swing position against the biasing force of the torsion spring. The dancer roller 12 is disposed at a position where the force received from the photographic paper 2 and the urging force of the torsion spring substantially coincide. In FIG. 1 and FIG. 2, an example of a position where the force received from the photographic paper 2 and the biasing force by the torsion spring substantially coincide (hereinafter referred to as a “swinging stable position”) is drawn with a solid line. The oscillation stable position of the roller 12 changes when the conveyance speed of the photographic paper 2 changes, for example.
[0038]
<Configuration near the conveyance roller pair 20>
  The conveyance roller pair 20 is disposed on the downstream side of the adapter unit 10. As described above, the conveying roller pair 20 is for conveying the photographic paper 2 further downstream after the photographic paper 2 is supplied from the adapter unit 10. Here, the conveyance roller pair 20 is connected to a motor 20a (see FIG. 10) for driving the rotation of the pair of rollers, and the rotation speed (number of rotations) of the motor 20a is controlled by the controller 200. Accordingly, the conveyance speed (feeding speed) of the photographic paper 2 by the conveyance roller pair 20 can be adjusted as appropriate by the controller 200. Note that the conveyance roller pair 20 changes the conveyance direction of the photographic paper 2 from the vertically upward direction to the horizontal direction.
[0039]
  Further, a paper end sensor 91, a splice sensor 92, and a paper cutter 18 are disposed between the adapter unit 10 and the conveying roller pair 20 in order from the upstream side to the downstream side. The paper end sensor 91 is for detecting the rear end of the photographic paper 2. The splice sensor 92 is used to detect a joint when the photographic paper 2 wound around the wound body 2a is a combination of a plurality of photographic papers having a relatively short length. The paper cutter 18 is for cutting the photographic paper 2, and can cut the long photographic paper 2 for each length that can be wound around the winding unit 100, for example.
[0040]
  Here, the paper end sensor 91 is an optical sensor including a pair of a light emitting element such as an LED and a light receiving element such as a photodiode disposed at a position where the light emitted therefrom can be received, and a position corresponding thereto. It is possible to detect whether or not the photographic paper 2 is placed on the printer 200 and supply the detection signal to the controller 200. As will be described below, the exposure apparatus 1 is provided with a number of paper sensors, all of which have the same configuration as that of the paper end sensor 91, and each detection signal is sent to the controller 200. To supply.
[0041]
<Configuration of dancer unit 30>
  The dancer unit 30 having a dancer mechanism is provided on the downstream side of the conveying roller pair 20. Here, FIG. 3 is a side view showing a schematic configuration of the dancer section. FIG. 4 is a cross-sectional view (cross-sectional view taken along line IV-IV in FIG. 3) showing a schematic configuration of the dancer unit. FIG. 5 is a diagram for explaining a configuration in which the holding member holds the dancer roller. FIG. 6 is a top view showing a schematic configuration of the dancer unit. FIG. 7 is an enlarged view of range A and range B of FIG.
[0042]
  The dancer unit 30 forms a curved portion in the photographic paper 2 to separate the conveyance of the photographic paper 2 upstream from the dancer unit 30 and the conveyance of the photographic paper 2 downstream from the dancer unit 30. Is. In addition, a paper sensor 93 is disposed between the transport roller pair 20 and the dancer unit 30.
[0043]
  As shown in FIG. 4, the dancer unit 30 includes a guide roller 31, a dancer roller 32, and a guide roller 33 that are sequentially arranged from the upstream side toward the downstream side. The guide roller 31 and the guide roller 33 are cylindrical members, and are supported by a pair of side walls 40 (see FIG. 3) provided so as to be rotatable around their axes and sandwiching the conveyance path of the photographic paper 2. ing.
[0044]
  As shown in FIG. 3, the dancer roller 32 is a substantially cylindrical roller configured by a support shaft 32a and a roller portion 32b. The dancer roller 32 is in contact with the photographic paper 2 between the guide roller 31 and the guide roller 33 and in the vertical direction (the direction in which the length of the photographic paper 2 between the guide roller 31 and the guide roller 33 changes). ) Can be moved. The dancer roller 32 is biased vertically downward (in the direction of increasing the length of the photographic paper 2 between the guide roller 31 and the guide roller 33) by its own weight.
[0045]
  Further, both ends of the support shaft 32a of the dancer roller 32 are rotatably held by holding members 34 and 35, respectively. Here, on the surface of the holding member 34 facing the holding member 35, as shown in FIG. 5A, a long hole 34a extending in the vertical direction is formed. One end of the dancer roller 32 is held by inserting one end of the support shaft 32 a into the long hole 34 a of the holding member 34. Similarly, as shown in FIG. 5B, the other end portion of the dancer roller 32 has a support shaft 32a in a long hole 35a formed in a surface facing the holding member 34 of the holding member 35 and extending in the vertical direction. It is hold | maintained by inserting the other end part.
[0046]
  Therefore, the dancer roller 32 is held with respect to the holding member 34 and the holding member 35 in a state in which the dancer roller 32 can move in the vertical direction within the range of the long holes 34a and 35a. Here, when the holding member 34 and the holding member 35 are disposed at their uppermost positions (when the leading end of the photographic paper 2 is conveyed between the guide roller 31 and the guide roller 33), and the holding member 34 and the holding member 35 are supported from below by the moving members 42 and 43, the support shaft 32 a of the dancer roller 32 is caused by the weight of the dancer roller 32 and the length of the long hole 34 a of the holding member 34 and the length of the holding member 35. It arrange | positions at each lower end part of the hole 35a. On the other hand, the holding member 34 and the holding member 35 are not supported from below by the moving members 42, 43, and the photographic paper 2 is conveyed through the dancer section 30, whereby the upward force from the photographic paper 2 to the dancer roller 32 is achieved. Is added, the support shaft 32a of the dancer roller 32 is disposed at the upper end of each of the long hole 34a of the holding member 34 and the long hole 35a of the holding member 35 (see FIG. 5).
[0047]
  Further, as shown in FIGS. 3 and 7, the holding members 34 and 35 are formed with through holes 34 b and 35 b that penetrate the holding members 34 and 35 in the vertical direction, respectively. Here, the dancer section 30 has shafts 36 and 37 extending in the vertical direction so as to sandwich the conveyance path of the photographic paper 2 between the guide roller 31 and the guide roller 32 as shown in FIGS. Has been placed. A shaft 36 is inserted into the through hole 34 a of the holding member 34, and a shaft 37 is inserted into the through hole 35 a of the holding member 35. Therefore, the holding members 34 and 35 can move in the vertical direction along the shafts 36 and 37. The holding members 34 and 35 can move together with the dancer roller 32 when the dancer roller 32 moves downward due to its own weight.
[0048]
  Further, as described above, both end portions of the support shaft 32 a of the dancer roller 32 are inserted into the long holes 34 a and 35 a of the holding member 34 and the holding member 35, so that the holding member 34 and the holding member 35 are separated. It is held so as to be movable in the vertical direction. Accordingly, when the photographic paper 2 is in contact with the dancer roller 32, even if the portion of the photographic paper 2 that is in contact with the dancer roller 32 is inclined in the width direction, either of the both ends of the support shaft 32a of the dancer roller 32 is Only one of them moves downward from the respective upper ends of the long hole 34a of the holding member 34 and the long hole 35a of the holding member 35, whereby the holding member 34 and the holding member 35 are moved along the shafts 36 and 37. Almost never move.
[0049]
  Here, the cross-sectional shape of the through hole 34b of the holding member 34 is substantially circular as shown in FIG. 7A, and the cross-sectional shape of the through hole 35b of the holding member 35 is as shown in FIG. 7B. And a substantially elliptical shape having a long axis along the width direction of the photographic paper 2 (the axial direction of the dancer roller 32). Accordingly, the holding member 34 cannot move in the width direction of the photographic paper 2 when moving in the vertical direction along the shaft 34, but the holding member 35 is moved in the vertical direction along the shaft 37. The photographic paper 2 can be moved in the width direction.
[0050]
  A guide member 38 having a surface facing the dancer roller 32 and the conveyance path of the photographic paper 2 below the dancer roller 32 is attached to the holding members 34 and 35. Therefore, the dancer roller 32 and the guide member 38 can move together while maintaining a state separated by a predetermined interval.
[0051]
  As shown in FIG. 3, sensors 41 a to 41 d for detecting the position of the holding member 34 are arranged on one side (left side in FIG. 3) of the pair of side walls 40. The sensors 41 a to 41 d can detect whether or not the holding member 34 is in a position facing them, and the detection signal is supplied to the connected controller 200. Further, the sensors 41a to 41d are arranged in order from the upper side to the lower side (along the moving direction of the holding member 34) and separated from each other by a predetermined distance. Here, the predetermined distance between the sensors 41a to 41d is set to be substantially the same as the height of the holding member 34 (the length in the moving direction). Accordingly, the holding member 34 is always detected by only one of the sensors 41a to 41d.
[0052]
  As described above, the position of the holding member 34 is detected by the sensors 41a to 41d, whereby the controller 200 detects the position of the dancer roller 32 held by the holding member 34, that is, the curvature of the photographic paper 2 at the dancer unit 30. The length of the part can be detected.
[0053]
  Here, the sensor 41a is provided at a position where the holding member 34 can be detected when the holding member 34 moves to the uppermost position (illustrated by a two-dot chain line in FIG. 3). Therefore, when the holding member 34 is detected by the sensor 41a, the photographic paper 2 is conveyed while being guided by the guide member 38 without being pressed downward by the dancer roller 32. 2 curved portions are hardly formed. That is, the photographic paper 2 is conveyed in the dancer unit 30 without being curved (maintained substantially horizontal).
[0054]
  When the holding member 34 moves downward from the state in which the holding member 34 is detected by the sensor 41a, the holding member 34 is not detected by the sensor 41a, and at the same time, the holding member 34 is detected by the sensor 41b. become.
[0055]
  Subsequently, when the holding member 34 further moves downward, the holding member 34 is not detected by the sensor 41b, and the holding member 34 is detected by the sensor 41c almost simultaneously. The sensor 41b is provided so that the length of the curved portion of the photographic paper 2 at the dancer unit 30 at this time becomes the predetermined length A.
[0056]
  Thereafter, when the holding member 34 moves further downward, the holding member 34 is not detected by the sensor 41c, and at the same time, the holding member 34 is detected by the sensor 41d. The sensor 41c is provided so that the length of the curved portion of the photographic paper 2 at the dancer unit 30 at this time is a predetermined length B.
[0057]
  Accordingly, the controller 200 detects that the length of the curved portion of the photographic paper 2 in the dancer unit 30 has reached the predetermined length A or the predetermined length B based on the detection signals from the sensors 41a to 41d. be able to.
[0058]
  Further, as described above, the shafts 36 and 37 are fitted into the through holes 34b and 35b of the holding members 34 and 35, respectively. Moving members 42 and 43 that are movable along the shafts 36 and 37 are disposed below the holding members 34 and 35 of the shafts 36 and 37, respectively. The moving members 42 and 43 are also formed with through-holes (not shown) penetrating in the vertical direction similarly to the holding members 34 and 35, and the shafts 36 and 37 are inserted into the through-holes. . Here, the moving members 42 and 43 are coupled to a drive mechanism 48 (see FIG. 10) connected to the controller 200. Therefore, the controller 200 can move the moving members 42 and 43 in the vertical direction by driving the drive mechanism 48.
[0059]
  Coil springs 44 and 45 fitted into shafts 36 and 37 are disposed above the moving members 42 and 43 (between the moving members 42 and 43 and the holding members 34 and 35), respectively. When the moving members 42 and 43 are disposed at the lowermost positions (positions shown in FIG. 3), the coil springs 44 and 45, for example, the dancer roller 32 does not come into contact with the photographic printing paper 2 and the weight of the dancer roller 32 is reduced. When the holding members 34 and 35 together with the dancer roller 32 move downward (dropped) along the shafts 36 and 37, they have the function of a cushion that gradually reduces the moving speed of the holding members 34 and 35. The lower end portions of the coil springs 44 and 45 are in contact with the upper surfaces of the moving members 42 and 43, respectively.
[0060]
  As described above, the holding members 34 and 35, the coil springs 44 and 45, and the moving members 42 and 43 that are movable in the vertical direction are arranged on the shafts 36 and 37 in order from the upper side to the lower side. Therefore, when the moving members 42 and 43 are moved upward from the lowermost position shown in FIG. 3 by the controller 200, the upper ends of the coil springs 44 and 45 above the moving members 42 and 43 are first held by the holding members 34 and 35. It comes to contact | abut to the lower end part. Thereafter, when the moving members 42 and 43 push up the holding members 34 and 35 via the coil springs 44 and 45, the dancer roller 32 moves upward together with the holding members 34 and 35.
[0061]
<Configuration near the conveyance roller pair 21>
  The conveyance roller pair 21 is disposed on the downstream side of the dancer unit 30. Here, the conveyance roller pair 21 is connected to a motor 21 a (see FIG. 10) for rotationally driving it, and the rotation speed (number of rotations) of the motor is controlled by the controller 200. Therefore, the conveyance speed of the photographic paper 2 by the conveyance roller pair 21 can be adjusted as appropriate by the controller 200. The conveyance roller pair 21 changes the conveyance direction of the photographic paper 2 from the horizontal direction to the vertical downward direction. A paper sensor 94 is disposed between the dancer unit 30 and the transport roller pair 21.
[0062]
<Configuration of Image Information Adding Unit 50>
  The image information adding unit 50 is provided on the downstream side of the transport roller pair 21. The image information adding unit 50 includes a back printing unit 51 and a punch 52. The back printing unit 51 is for printing image information such as an image number (frame number), an exposure condition, an order number, and a serial number on the back surface of the photographic paper 2. The punch 52 is for forming a small-diameter hole as a mark on the photographic paper 2 at a position where the conveyance speed is governed by the operation state of the conveyance roller pair 21. Here, the punch 52 has a cut mark as a mark when a plurality of images are continuously exposed on the long photographic paper 2 and cut at the leading end and the trailing end of the images. It is possible to form an order mark that is a mark indicating a break between orders for the images. The punch 52 is driven by a motor 52a connected to the controller 200 (see FIG. 10).
[0063]
  In the present embodiment, the punch 52 has at least two order marks in the vicinity of the front end portion and the rear end portion where the exposure processing of the long photographic paper 2 is not performed regardless of the order separation for the image. Is supposed to form. Here, the order mark formed in the vicinity of the front end portion and the rear end portion of the photographic paper 2 is a mark for detecting a transport system error, as will be described in detail later, together with an order mark indicating an order break for the image. Used as Therefore, in the present embodiment, it is possible to detect whether or not a transport system error has occurred at the start of image formation and the end of image formation on the long photographic paper 2.
[0064]
<Configuration of the first slack portion 60>
  The first slack unit 60 is provided on the downstream side in the transport direction of the image information adding unit 50. The first slack portion 60 is for forming a slack portion on the upstream side of the exposure unit 70 on the photographic paper 2 conveyed from above to below. A paper sensor 95 is disposed between the image information adding unit 50 and the first slack unit 60.
[0065]
  The first slack portion 60 includes a driven roller pair 22, a transport roller pair 23, and paper sensors 61 and 62. The driven roller pair 22 is disposed below the transport roller pair 21 and in the vicinity of the upper end portion of the first slack portion 60. Further, the transport roller pair 23 is disposed below the driven roller pair 22 and at a predetermined interval from the driven roller pair 22. Here, the conveyance roller pair 23 is connected to a motor 23a (see FIG. 10) for rotationally driving it, and the rotation speed (number of rotations) of the motor 23a is controlled by the controller 200. Therefore, the conveyance speed of the photographic paper 2 by the conveyance roller pair 23 can be adjusted as appropriate by the controller 200.
[0066]
  Further, the conveying roller pair 23 can take either a state in which the photographic paper 2 is clamped or a state in which the photographic paper 2 is not clamped. Here, in a state where the photographic paper 2 is sandwiched, a conveyance force can be applied to the photographic paper 2, and in a state where the photographic paper 2 is not sandwiched, the photographic paper 2 can freely move between the pair of conveyance rollers 23. It is in a movable state. As will be described later, while the exposure unit 70 exposes the photographic paper 2, the conveyance roller pair 23 is controlled by the controller 200 so as not to sandwich the photographic paper 2.
[0067]
  Further, between the driven roller pair 22 and the conveying roller pair 23, the photographic paper 2 is appropriately conveyed when the leading end of the photographic paper 2 is conveyed between the driven roller pairs 22 and 23. In addition, a guide member 65 is disposed at a position (a position indicated by a broken line in FIG. 1) where the leading end portion of the photographic paper 2 can be guided from the driven roller pair 22 to the conveying roller pair 23. The guide member 65 can form a slack portion between the driven roller pair 22 and the conveying roller pair 23 when the leading end of the photographic paper 2 does not pass between the driven roller pair 22 and the conveying roller pair 23. It is configured to be movable to a position (a position indicated by a solid line in FIG. 1).
[0068]
  The paper sensors 61 and 62 are for detecting the length of the slack portion of the photographic paper 2 at the first slack portion 60. Here, the paper sensor 61 is used to maintain the length of the slack portion of the photographic paper 2 at the first slack portion 60 at a predetermined length C or more. The paper sensor 62 is used to maintain the length of the slack portion of the photographic paper 2 at the first slack portion 60 at a predetermined length D which is set in advance. Accordingly, the paper sensor 61 is disposed at a position where the bottom of the slack portion of the photographic paper 2 can be detected when the length of the slack portion of the photographic paper 2 at the first slack portion 60 reaches a predetermined length C. The paper sensor 62 is disposed at a position where the bottom of the slack portion of the photographic paper 2 can be detected when the length of the slack portion of the photographic paper 2 at the first slack portion 60 reaches a predetermined length D. Has been.
[0069]
  A cut mark and an order mark formed on the photographic paper 2 can be detected between the first slack portion 60 and the exposure unit 70 at a position where the conveyance speed is governed by the operation state of the conveyance roller pair 24. A mark sensor 96 is arranged.
[0070]
<Configuration near exposure unit 70>
  The exposure unit 70 is provided on the downstream side of the first slack portion 60. Here, FIG. 8 is a top view showing a schematic configuration of the exposure unit. FIG. 9 is a partial side view showing a schematic configuration of the exposure unit.
[0071]
  A conveying roller pair 24 and a pressure roller pair 25 are disposed at a position facing the exposure unit 70. Accordingly, the photographic paper 2 supplied to the exposure unit 70 by the transport roller pair 23 is transported so as to face the exposure unit 70 while being sandwiched between the transport roller pair 24 and the pressure roller pair 25. Here, the conveyance roller pair 24 is connected to a motor 24a (see FIG. 10) for driving the rotation of the conveyance roller pair 24, and the rotation speed (number of rotations) of the motor 24a is controlled by the controller 200. Accordingly, the transport speed of the photographic paper 2 by the transport roller pair 24 can be adjusted as appropriate by the controller 200.
[0072]
  As shown in FIG. 8, the exposure unit 70 includes a blue SHG (Second Harmonic Generation) laser unit 71B, a green SHG laser unit 71G, and a red LD (Laser Diode) 71R in a housing 70a. The blue SHG laser unit 71B, the green SHG laser unit 71G, and the red LD 71R function as light sources that emit laser beams having wavelengths of blue component, green component, and red component, respectively.
[0073]
  Inside the blue SHG laser unit 71B and the green SHG laser unit 71G, although not shown, a solid-state laser such as a YAG laser and a laser beam emitted from the solid-state laser respectively correspond to the blue or green component laser light. A wavelength variable unit including a second harmonic generation unit for extracting the second harmonic is provided, and laser light of the second harmonic component is emitted. In the configuration of the present embodiment, a solid-state laser is used as a means for emitting basic laser light. However, the present invention is not limited to this, and for example, an LD can be used.
[0074]
  On the other hand, the red LD 71R can directly emit red component laser light. On the emission side of the red LD 71R, there is disposed a lens group 72R for shaping the red laser light emitted therefrom and guiding it to the light entrance of the next AOM 73R. Instead of the red LD 71R, a red SHG laser unit configured in the same manner as the blue SHG laser unit 71B can be used. Further, the laser light intensity may be modulated by directly modulating the output from the red LD 71R without providing the AOM 73R for the red LD 71R.
[0075]
  The laser beams emitted from the blue SHG laser unit 71B, the green SHG laser unit 71G, and the red LD 71R are guided to the light entrances of acousto-optic modulators (AOMs) 73B, 73G, and 73R, and the respective lasers. After the light is modulated in accordance with the image data, the light amount of each laser beam is adjusted in the light control sections 74B, 74G, and 74R.
[0076]
  AOMs 73B, 73G, and 73R are optical modulators that utilize a so-called acousto-optic diffraction, which is a diffraction phenomenon caused by a refractive index distribution created in a transparent medium by sound waves acting as a phase diffraction grating. The intensity of the diffracted light is modulated by changing the intensity. Accordingly, AOM drivers (not shown) are connected to the AOMs 73B, 73G, and 73R, respectively, and high frequency signals whose amplitudes are modulated according to image data are input from these AOM drivers. Then, an ultrasonic wave corresponding to the high-frequency signal is propagated in the acousto-optic medium, and when laser light is transmitted through the acousto-optic medium, the acousto-optic effect acts to produce diffraction, which corresponds to the amplitude of the high-frequency signal. Intense laser light is emitted from the AOMs 73B, 73G, and 73R as diffracted light.
[0077]
  The dimmers 74B, 74G, and 74R are configured by, for example, an ND filter or a rotating plate provided with a plurality of openings having different sizes. Light emitting elements such as semiconductor lasers and solid-state lasers have a light amount range in which light can be emitted in a stable state. Therefore, by adjusting the light amount by the light control units 74B, 74G, and 74R, the color development characteristics of photographic paper Accordingly, it is possible to perform exposure in a light amount range that provides a wide dynamic range.
[0078]
  The laser beams emitted from the light control units 74B, 74G, and 74R are reflected in the direction toward the reflection mirror 76 by the dichroic mirrors 75B and 75G or the mirror 75R. Here, each of the dichroic mirrors 74B and 75G has a property of reflecting only the laser light having the wavelength of the blue component or the green component and transmitting the light of other wavelengths. On the other hand, the mirror 75R may be any mirror that reflects the red component of the incident light. In the present embodiment, since the red laser light having only the wavelength of the red component is incident on the mirror 75R, a mirror that totally reflects the incident light is used as the mirror 75R.
[0079]
  Accordingly, the red laser light reflected by the mirror 75R and transmitted through the dichroic mirrors 75G and 75B and the green laser light reflected by the dichroic mirror 14G pass through the dichroic mirror 75B and reach the reflection mirror 76. That is, the laser light traveling from the dichroic mirror 75B toward the reflection mirror 76 becomes a combined laser light composed of red, green, and blue component laser light modulated according to the image data.
[0080]
  The synthetic laser light is reflected by the reflection mirror 76, passes through the cylindrical lens 77, and then reaches the polygon mirror 78. Here, the cylindrical lens 77 is a lens that condenses the combined laser light reflected by the reflection mirror 76 on the reflection surface of the polygon mirror 78 in the sub-scanning direction. The cylindrical lens 77 is used to perform correction (surface tilt correction) when a surface tilt error (an error in which the normal direction of the reflective surface deviates from the normal main scanning surface) occurs on the reflection surface of the polygon mirror 78. is there.
[0081]
  The polygon mirror 78 is a rotating body provided such that a plurality of reflecting surfaces form a regular polygon, and is rotated by a polygon driver 78a. The combined laser light emitted from the reflecting mirror 76 through the cylindrical lens 77 is reflected by one reflecting surface of the polygon mirror 78 and travels in the direction of the photographic paper 2. The reflection direction of the combined laser beam on the polygon mirror 78 moves in the main scanning direction according to the rotation of the polygon mirror 78. When the reflection of the combined laser beam on one reflecting surface is finished by the rotation of the polygon mirror 78, the irradiation of the combined laser beam is transferred to the reflecting surface adjacent to the reflecting surface, and the reflected laser beam is reflected in the main scanning direction within the same range. The direction moves. In this way, one scanning line is scanned by one reflecting surface, and the next scanning line is scanned by the adjacent reflecting surface. Therefore, the time lag between the adjacent scanning lines in the sub-scanning direction is extremely reduced. It can be made smaller.
[0082]
  An fθ lens 79 is disposed on the optical path from the polygon mirror 78 toward the photographic paper 2. The fθ lens 79 is an optical system for correcting image distortion in the vicinity of both ends of the scanning surface due to the combined laser light irradiated onto the photographic paper 2 from the polygon mirror 78, and includes a plurality of lenses. The distortion of the image in the vicinity of both ends of the scanning surface is caused by the difference in the length of the optical path from the polygon mirror 78 to the photographic paper 2.
[0083]
  Further, a mirror 171 and a synchronization sensor 172 are provided outside the main scanning range of the combined laser beam from the polygon mirror 78 to the photographic paper 2. The mirror 171 is disposed at a position just outside the direction of the main scanning start point when viewed from the polygon mirror 78. That is, the combined laser light reflected from one reflecting surface of the polygon mirror 78 first strikes the mirror 171 and the exposure on the photographic paper 2 is performed in the main scanning direction immediately after that.
[0084]
  Here, the direction of the reflecting surface of the mirror 171 is such that the combined laser light from the polygon mirror 78 is reflected in the direction toward the synchronization sensor 172. The length of the optical path from the polygon mirror 78 to the synchronization sensor 172 via the mirror 171 is substantially equal to the length of the optical path from the polygon mirror 78 to the start point of main scanning on the photographic paper 2.
[0085]
  The synchronization sensor 172 is a sensor that detects light, and laser light emitted from the blue SHG laser unit 71B, the green SHG laser unit 71G, and the red LD 71R by laser light received from the polygon mirror 78 via the mirror 171. This is used to adjust the modulation timing of. Note that the synchronization sensor 172 is connected to the controller 200.
[0086]
  By the way, as shown in FIG. 9, a long hole 173 is formed in the housing 70a so that the combined laser light reflected by the polygon mirror 78 is emitted to the outside. In addition, a shutter 174 is disposed outside the housing 70 a and at a position adjacent to the exit portion of the long hole 173. The shutter 174 is formed of a member that does not allow the synthetic laser beam to pass (has a light shielding property), and has a rectangular plate-like portion 175 having a size that can sufficiently cover the long hole 173 of the housing 70a. And a support part 176 formed at one end of the part 175. Here, a shaft member 177 is fitted into the opening formed in the central portion of the support portion 176, and a motor 178 (see FIG. 10) is connected to the shaft member 177. Accordingly, when the shaft member 177 is rotated by driving the motor 178, the shutter 174 is rotated about the shaft member 177 as a fulcrum (blocking position; broken line in FIG. 9). And a position to be opened (open position; depicted by a solid line in FIG. 9).
[0087]
<Configuration of the second slack portion 80>
  The second slack portion 80 is provided on the downstream side of the exposure unit 70. The second slack portion 80 is for forming a slack portion in the photographic paper 2 on the downstream side of the exposure unit 70 in the photographic paper 2 conveyed from above to below. A paper sensor 97 is disposed between the exposure unit 70 and the second slack portion 80.
[0088]
  The second slack portion 80 includes the conveyance roller pair 26 and paper sensors 81 and 82. The conveyance roller pair 26 is arranged at a position shifted in a direction approaching the winding unit 100 by a predetermined distance from almost directly below the pressure roller pair 25. Here, the conveyance roller pair 26 is connected to a motor 26a (see FIG. 10) for rotating the conveyance roller pair 26, and the rotation speed (number of rotations) of the motor 26a is controlled by the controller 200. Therefore, the conveyance speed of the photographic paper 2 by the conveyance roller pair 26 can be adjusted as appropriate by the controller 200.
[0089]
  In addition, the photographic paper 2 is properly conveyed between the pressure roller pair 25 and the conveying roller pair 26 when the leading end of the photographic paper 2 is conveyed between the pressure roller pair 25 and the conveying roller pair 26. For this purpose, a guide member 85 is disposed at a position (a position indicated by a broken line in FIG. 1) where the leading end of the photographic paper 2 can be guided from the pressure roller pair 25 to the transport roller pair 26. The guide member 85 can form a slack portion between the pressure roller pair 25 and the conveyance roller pair 26 when the leading end portion of the photographic paper 2 does not pass between the pressure roller pair 25 and the conveyance roller pair 26. It is configured to be movable to a position (a position indicated by a solid line in FIG. 1).
[0090]
  The paper sensors 81 and 82 are for detecting the length of the slack portion of the photographic paper 2 at the second slack portion 80. Here, the paper sensor 81 is used to maintain the length of the slack portion of the photographic paper 2 at the second slack portion 80 at a predetermined length E or more. The paper sensor 82 is used to maintain the length of the slack portion of the photographic paper 2 at the second slack portion 80 at a predetermined length F that is set to be substantially constant. Accordingly, the paper sensor 81 is disposed at a position where the bottom of the slack portion of the photographic paper 2 can be detected when the length of the slack portion of the photographic paper 2 at the second slack portion 80 reaches a predetermined length E. The paper sensor 82 is disposed at a position where the bottom of the slack portion of the photographic paper 2 can be detected when the length of the slack portion of the photographic paper 2 at the second slack portion 80 reaches a predetermined length F. Has been.
[0091]
  In the present embodiment, the predetermined length E of the slack portion of the photographic paper 2 at the second slack portion 80 is rewound by the photographic paper 2 arranged at a position facing the exposure unit 70 as will be described later. In consideration of the fact that the printing paper 2 may be rewound, it is set to a value larger than at least the maximum rewound amount that the photographic paper 2 may be rewound.
[0092]
  As described above, the take-up unit 100 for taking up the exposed photographic paper 2 can be mounted on the downstream side of the second slack portion 80. A shaft 102 is rotatably supported by the winding unit 100, and the photographic paper 2 conveyed downstream by the conveying roller pair 26 of the second slack portion 80 can be sequentially wound.
[0093]
<Configuration of Controller 200>
  Next, the configuration of the controller 200 of the exposure apparatus 1 will be described with reference to FIG. FIG. 10 is a simplified block diagram of the main part of the controller 200 of the exposure apparatus 1.
[0094]
  As shown in FIG. 10, the controller 200 includes motors 15 a, 20 a, 21 a, 23 a, 24 a, 26 a for driving the conveyance roller pairs 15, 20, 21, 23, 24, 26, and paper sensors 61, 62. 81, 82, 93, 95, 96, sensors 41a to 41d, a drive mechanism 48 for driving the moving members 42, 43 of the dancer unit 30, and a punch 52 of the image information adding unit 50 A motor 52a and a motor 178 for driving the shutter 174 of the exposure unit 70 are connected to each other.
[0095]
  The controller 200 includes a ROM that stores control programs and data for various operations related to the exposure apparatus 1, a CPU that executes various calculations to generate signals for controlling the operations of the respective units of the exposure apparatus 1, and a CPU Members such as a RAM for temporarily storing data such as calculation results are included. By these various members and software, the conveyance system control unit 201, the conveyance distance deriving unit 202, the conveyance distance comparison unit 203, the error detection unit 204, the dancer unit control unit 205, the information addition unit control unit 206, the exposure A unit control unit 207 and a sensor management unit 208 are formed.
[0096]
  The transport system control unit 201 controls transport speeds by the transport roller pairs 15, 20, 21, 23, 24, and 26, respectively. Here, the conveyance system control unit 201 supplies a drive signal to each motor connected to each conveyance roller pair in order to drive each conveyance roller pair. Since a stepping motor is used, a pulse signal having a predetermined width corresponding to the conveyance speed is supplied as a drive signal from the conveyance system control unit 201 to each motor. Therefore, the conveyance system control unit 201 can appropriately change the conveyance speed of each conveyance roller pair by changing the magnitude of the predetermined width of the pulse signal.
[0097]
  The conveyance distance deriving unit 202 derives the conveyance distance of the photographic paper 2 by the pair of conveyance rollers 21 corresponding to the two order marks based on the difference in the formation times of the two order marks formed by the punch 52. . In other words, the information adding unit control unit 206 controls the punch 52 to form an order mark at a position corresponding to the cut in the order of the photographic paper 2, but the formation time of one order mark and the formation of the next order mark. The time can be recognized and the time difference between the two can be recognized. Therefore, the conveyance distance deriving unit 202 is supplied from the conveyance system control unit 201 to the motor 21a that drives the conveyance roller pair 21 between the formation time of one order mark and the formation time of the next order mark. Based on the signal, the conveyance distance of the photographic paper 2 by the conveyance roller pair 21 at the time difference can be derived.
[0098]
  Further, the transport distance of the photographic paper 2 by the transport roller pair 24 corresponding to the two order marks is derived based on the difference between the detection times of the two order marks by the mark sensor 96. That is, the sensor management unit 208 can recognize the detection time of one order mark and the detection time of the next order mark from the detection signal supplied from the mark sensor 96 and also recognize the time difference between the two. be able to. Therefore, the conveyance distance deriving unit 202 is supplied from the conveyance system control unit 201 to the motor 24a that drives the conveyance roller pair 24 between the detection time of one order mark and the detection time of the next order mark. Based on the signal, the conveyance distance of the photographic paper 2 by the conveyance roller pair 24 at the time difference can be derived.
[0099]
  The conveyance distance comparison unit 203 compares the conveyance distance of the photographic paper 2 by the conveyance roller pair 21 derived by the conveyance distance deriving unit 202 with the conveyance distance of the photographic paper 2 by the conveyance roller pair 24. Specifically, the transport distance comparison unit 203 calculates a difference between the transport distance of the photographic paper 2 by the transport roller pair 21 and the transport distance of the photographic paper 2 by the transport roller pair 24.
[0100]
  In the error notification unit 204, the difference between the conveyance distance of the photographic paper 2 by the conveyance roller pair 21 and the conveyance distance of the photographic paper 2 by the conveyance roller pair 24 calculated by the conveyance distance comparison unit 203 is equal to or greater than a predetermined value (threshold). In this case, it is determined that a problem has occurred in the transport system (transport system error), and the fact is notified to the operator. Here, the predetermined value is a preset value, and when a trouble occurs in the transport system, for example, the image formed on the photographic paper 2 deteriorates due to the photographic paper 2 not being transported properly. It is set to a value that can detect the situation. Further, the method of notifying the operator of the transport system error can be arbitrarily changed as long as the notification to the operator is properly performed, for example, that effect is displayed on a display provided in the exposure apparatus 1.
[0101]
  The dancer control unit 205 moves the moving members 42 and 43 that can contact the lower ends of the holding members 34 and 35 that hold the dancer roller 32 in the vertical direction by supplying a drive signal to the drive mechanism 48. It is. Therefore, when the leading end of the photographic paper 2 is conveyed between the guide rollers 31 and 33, the dancer unit control unit 205 has the dancer roller 32 and the guide member 38 arranged at the uppermost part of the movable range below. The moving members 42 and 43 are moved downward so as to be movable. Also, the dancer control unit 205 is configured such that when the leading end of the photographic paper 2 is conveyed between the guide rollers 31 and 33 or when the rear end of the photographic paper 2 is detected by the paper sensor 93 as described later, The moving members 42 and 43 are moved upward.
[0102]
  The information adding unit control unit 206 supplies a drive signal to the motor 52a to which the punch 52 is connected, whereby a cut mark and an order are placed on the photographic paper 2 at a position where the conveyance speed is governed by the operation state of the conveyance roller pair 21. A mark is formed. Here, the information adding unit control unit 206 can recognize the formation time of the cut mark and the order mark.
[0103]
  The exposure unit controller 207 supplies the drive signal to the motor 178 to which the shaft member 177 fitted to the shutter 174 is connected, thereby arranging the shutter 174 at either the closed position or the open position. . Therefore, the exposure unit controller 207 controls the shutter 174 when adjusting the modulation timing of the laser light emitted from the blue SHG laser unit 71B, the green SHG laser unit 71G, and the red LD 71R using the synchronization sensor 172 in the exposure unit 70. Move from the open position to the closed position. The exposure unit controller 207 can move the shutter 174 from the open position to the closed position even when the exposure unit 70 does not perform the exposure operation on the photographic paper 2.
[0104]
  The sensor management unit 208 receives a detection signal from each sensor provided in the exposure apparatus 1 and detects a detection timing in each sensor. Therefore, the sensor management unit 208 can detect, for example, that the rear end portion of the photographic paper 2 has reached the vicinity of the upstream side of the guide roller 31 by the paper sensor 93, and the curved portions of the dancer unit 30 by the sensors 41a to 41d. Further, the mark sensor 96 can detect that the cut mark or the order mark has reached a position facing it.
[0105]
  Next, the operation of the exposure apparatus according to the present embodiment will be described mainly with reference to FIG.
[0106]
<Operation near the adapter unit 10>
  First, the paper magazine 6 that houses the wound body 2 a of the photographic paper 2 is attached to the adapter unit 10. Then, the photographic paper 2 that has been manually unrolled from the wound body 2a and pulled out from the housing 5 is conveyed to the guide rollers 11, 13, and 14 and the dancer roller 12 of the adapter unit 10. While being arranged so as to properly contact along the path, it is set so that the vicinity of the tip is sandwiched between the conveying roller pair 15.
[0107]
  Thereafter, the conveyance roller pair 15 is driven by the controller 200, whereby the photographic paper 2 is sequentially drawn out from the paper magazine 6 and conveyed downstream. Here, when the photographic paper 2 is conveyed to the downstream side by the conveyance roller pair 15 with respect to the vicinity of the front end portion of the photographic paper 2 and the drawing of the photographic paper 2 from the paper magazine 6 is started, the conveyance system control unit 201 performs conveyance rollers. 15, the conveyance speed of the photographic paper 2 is increased stepwise. In other words, in the present embodiment, when the wound body 2a in the paper magazine 6 is stopped, first, the conveyance speed of the photographic paper 2 by the conveyance roller pair 15 is a relatively low conveyance speed V0 for a predetermined time. Be transported. Thereafter, the conveyance speed by the conveyance roller 15 is conveyed at a conveyance speed V1 that is faster than the conveyance speed V0.
[0108]
  Here, in a state where the wound body 2a in the paper magazine 6 is stopped, the dancer roller 12 in the adapter unit 10 is disposed at the original position. As the photographic paper 2 is pulled out of the paper magazine 6 by the conveying roller pair 15 while the conveying speed by the conveying roller pair 15 increases from 0 to V0, the dancer roller 12 moves from the original position to the maximum swing position. Begins to swing toward. Subsequently, as the conveyance speed by the conveyance roller pair 15 increases from V0 to V1, the dancer roller 12 further moves toward the maximum swing position as the photographic paper 2 is pulled out from the paper magazine 6 by the conveyance roller pair 15. Swing. Thereafter, when the conveyance speed by the conveyance roller pair 15 reaches V1 and the increase in the conveyance speed is stopped (maintained at the conveyance speed V1), the dancer roller 12 hardly oscillates at the oscillation stable position.
[0109]
  At this time, the wound body 2 a that was initially in a stopped state starts to rotate by being pulled by the photographic paper 2 that is transported by the transport roller pair 15. And while the conveyance speed by the conveyance roller pair 15 rises from 0 to V1, the rotational speed of the wound body 2a increases as the conveyance speed by the conveyance roller pair 15 increases.
[0110]
  When the leading end portion of the photographic paper 2 is sandwiched between the conveyance roller pair 20, the photographic paper 2 is subsequently pulled out from the paper magazine 6 by the conveyance roller pair 20 controlled by the conveyance system control unit 201. It is transported downstream. Therefore, at this time, the conveyance roller pair 15 is driven to rotate in accordance with the movement of the photographic paper 2 conveyed by the conveyance roller pair 20. In the present embodiment, the photographic paper 2 conveyed at the conveyance speed V1 by the conveyance roller pair 15 enters the conveyance roller pair 20 while maintaining the conveyance speed V1, and thereafter, the conveyance roller pair 20 It is assumed that the photographic paper 2 is transported at the transport speed V1 without stopping.
[0111]
  Thereafter, the leading end of the photographic paper 2 conveyed downstream by the conveying roller pair 20 passes through the dancer unit 30 and reaches the conveying roller pair 21. Therefore, thereafter, the conveyance force is applied to the photographic paper 2 from both the conveyance roller pair 20 and the conveyance roller pair 21.
[0112]
<Operation near the dancer 30>
  When the leading end portion of the photographic paper 2 is sandwiched between the conveying roller pair 21, the dancer unit control unit 205 of the controller 200 moves the moving members 42 and 43 downward by the driving mechanism 48 so that the lowermost position thereof is reached. To place.
[0113]
  Then, the dancer roller 32 of the dancer unit 30 can move downward according to its own weight. When the dancer roller 32 abuts on the photographic paper 2 between the guide roller pair 31 and the guide roller pair 33 and pushes it downward, a curved portion is formed between the guide roller pair 31 and the guide roller pair 33. The At this time, the holding members 34 and 35 are hung from both ends of the support shaft 32 a of the dancer roller 32. Accordingly, at this time, the support shaft 32a of the dancer roller 32 is disposed at the upper ends of the long holes 34a and 35a of the holding members 34 and 35. In the curved portion between the guide roller pair 31 and the guide roller pair 33, a certain amount of tension is applied to the photographic paper 2 without slackening.
[0114]
  Therefore, when the conveyance speed of the photographic paper 2 by the conveyance roller pair 20 is higher than the conveyance speed of the photographic paper 2 by the conveyance roller pair 21, the printing image conveyed between the conveyance roller pair 20 and the conveyance roller pair 21. Although the length of the paper 2 is longer than the distance between the transport roller pair 20 and the transport roller pair 21, the excess portion is absorbed by the curved portion of the photographic paper 2 being formed in the dancer section 30. The Accordingly, it is possible to prevent the photographic paper 2 from being properly conveyed due to the looseness of the photographic paper 2 between the conveyance roller pair 20 and the conveyance roller pair 21.
[0115]
  Here, the length of the curved portion of the photographic paper 2 at the dancer unit 30 varies depending on the difference between the conveyance speed of the photographic paper 2 by the conveyance roller pair 20 and the conveyance speed of the photographic paper 2 by the conveyance roller pair 21. That is, as the conveyance speed of the photographic paper 2 by the conveyance roller pair 20 becomes larger than the conveyance speed of the photographic paper 2 by the conveyance roller pair 21, the length of the curved portion of the photographic paper 2 in the dancer unit 30 becomes longer. Further, after the curved portion of the photographic paper 2 is formed in the dancer unit 30, when the conveyance speed of the photographic paper 2 by the conveyance roller pair 20 becomes lower than the conveyance speed of the photographic paper 2 by the conveyance roller pair 21, the dancer unit. The length of the curved portion of the photographic paper 2 at 30 is also reduced.
[0116]
  The length of the curved portion of the photographic paper 2 in the dancer unit 30 is always detected by detecting the positions of the holding members 34 and 35 by the sensors 41a to 41d in the controller 200. Accordingly, the transport roller pair 20 and the transport roller pair 21 are appropriately controlled by the transport system control unit 201 based on the length of the curved portion of the photographic paper 2 in the dancer unit 30.
[0117]
  The dancer roller 32 is held by the holding members 34 and 35 so as to be freely displaceable in the vertical direction in accordance with the force received from the photographic paper 2, so that the vicinity of the lower end portion of the outer peripheral surface of the dancer roller 32 and the photographic paper 2 No gap is formed between them, and a uniform force is always applied from the dancer roller 32 to the photographic paper 2.
[0118]
<Operation in the vicinity of the image information adding unit 50>
  Thereafter, the leading end portion of the photographic paper 2 reaches the image information adding unit 50 by being conveyed by the conveying roller pair 21. In the image information adding unit 50, the punch 52 forms a cut mark for each image on the photographic paper 2 and also forms an order mark for each order. In addition, on the back side of the photographic paper 2, back printing such as an image number is performed by the back printing unit 51. In the present embodiment, as described above, in the image information adding unit 50, at least two order marks for detecting a transport system error are formed in the vicinity of the front end portion where the exposure processing of the long photographic paper 2 is not performed. Is done.
[0119]
<Operation in the vicinity of the first slack portion 60>
  Thereafter, the leading end of the photographic paper 2 is conveyed by the conveying roller pair 21, passes through the driven roller pair 22, is guided by the guide member 65, and is sandwiched between the conveying roller pair 23. Then, when the vicinity of the front end portion of the photographic paper 2 is sandwiched between the conveyance roller pair 23, the guide member 65 of the first slack portion 60 is moved from the guide position to the slack formation position. When the leading end of the photographic paper 2 enters the transport roller pair 23, the transport roller pair 23 is not driven, so the front end of the photographic paper 2 is held in a state of being sandwiched between the transport roller pair 23. Is done.
[0120]
  In this way, when the leading end portion of the photographic paper 2 is held by the conveyance roller pair 23 and the guide member 65 is in the slack formation position, the photographic paper 2 is further supplied to the first slack portion 60 by the conveyance roller pair 21. Then, as shown in FIG. 1, a slack portion of the photographic paper 2 is formed between the driven roller pair 22 and the conveying roller pair 23.
[0121]
  Here, the length of the slack portion of the photographic printing paper 2 of the first slack portion 60 varies depending on the difference between the conveyance speed by the conveyance roller pair 21 and the conveyance speed by the conveyance roller pair 23. Then, the transport system control unit 201 controls the transport roller pair 21 and the transport roller pair 23 so that the length of the slack portion of the photographic paper 2 of the first slack unit 60 is maintained at the predetermined length D.
[0122]
  In the present embodiment, the vicinity of the front end portion of the photographic paper 2 conveyed downstream by the conveying roller pair 23 reaches the conveying roller pair 24 and the pressure roller pair 25 facing the exposure unit 70, and then exposure is performed. While the unit 70 exposes the photographic paper 2, the photographic paper 2 disposed at a position facing the exposure unit 70 is always maintained at a constant speed by the conveying roller pair 24 and the pressure roller pair 25. At this time, the conveyance roller pair 23 is in a state in which the photographic paper 2 is not sandwiched. Accordingly, while the exposure unit 70 exposes the photographic paper 2, the length of the slack portion of the photographic paper 2 of the first slack portion 60 is maintained at a substantially predetermined length D, so Only 21 will be controlled.
[0123]
  Specifically, for example, when the paper sensor 62 detects that the length of the slack portion of the photographic paper 2 of the first slack portion 60 has increased to reach a predetermined length D, a predetermined time has elapsed from that point. Until the time elapses, the conveyance by the conveyance roller pair 21 is continued. When a predetermined time has elapsed, the conveyance of the photographic paper 2 by the conveyance roller pair 21 is stopped. Thereafter, when the paper sensor 62 detects that the length of the slack portion of the photographic paper 2 of the first slack portion 60 has decreased and does not reach the predetermined length D, until the predetermined time elapses from that point. The conveyance stop state by the conveyance roller pair 21 is continued. When a predetermined time has elapsed, the conveyance of the photographic paper 2 by the conveyance roller pair 21 is resumed. By repeating such control of the conveying roller pair 21, the length of the slack portion of the photographic paper 2 of the first slack portion 60 is maintained substantially constant at the predetermined length D.
[0124]
<Operation near exposure unit 70>
  When the length of the slack portion of the photographic paper 2 at the first slack portion 60 is maintained substantially constant at the predetermined length D, when the transport roller pair 24 and the pressure roller pair 25 facing the exposure unit 70 are reached, the exposure unit In 70, the photographic printing paper 2 supported by the conveying roller pair 24 and the pressure roller pair 25 is exposed. As described above, while the exposure by the exposure unit 70 is being performed, the photographic paper 2 disposed at a position facing the exposure unit 70 is always fixed by the transport roller pair 24 and the pressure roller pair 25. It is conveyed while maintaining the speed.
[0125]
  Here, the exposure position of each image on the photographic paper 2 in the exposure unit 70 is determined based on the position of the cut mark formed on the photographic paper 2 by the punch 52 of the image information adding unit 50. That is, as described above, since the cut mark is formed in the vicinity of the front end portion of each image, image exposure is started based on each image data from the position of the cut mark corresponding to the vicinity of the front end portion of each image. The Accordingly, when a cut mark is detected by the mark sensor 96 disposed on the upstream side of the exposure unit 70, the photographic paper 2 is further conveyed by a distance between the mark sensor 96 and the exposure position of the exposure unit 70. At that time, image exposure is started.
[0126]
<Operation in the vicinity of the second slack portion 80>
  The photographic paper 2 that has been exposed by the exposure unit 70 is conveyed further downstream while being conveyed by the conveying roller pair 24, and is further conveyed to the downstream side, and is sandwiched between the conveying roller pair 26. At this time, the leading end portion of the photographic paper 2 is guided in the direction toward the winding unit 100 along the guide member 85 of the second slack portion 80, and reaches the conveying roller pair 26. When the leading end portion of the photographic paper 2 is sandwiched between the conveying roller pair 26, the guide member 85 of the second slack portion 80 is moved from the guide position to the slack formation position. When the leading end of the photographic paper 2 enters the transport roller pair 26, the transport roller pair 26 is not driven, so the front end of the photographic paper 2 is held in a state of being sandwiched between the transport roller pair 26. Is done.
[0127]
  As described above, when the leading end portion of the photographic paper 2 is held by the conveying roller pair 26 and the guide member 85 is in the slack forming position, the photographic paper 2 is further supplied to the second slack portion 80 by the conveying roller pair 24. Then, the photographic paper 2 exposed by the exposure unit 70 travels by its own weight in the direction (vertically below) conveyed from the exposure unit 70 to the second slack portion 80 by the pressure roller pair 25, A slack portion is formed between the pressure roller pair 25 and the conveying roller pair 26.
[0128]
  Here, the length of the slack portion of the photographic printing paper 2 of the second slack section 80 varies depending on the difference between the transport speed by the transport roller pair 24 and the transport speed by the transport roller pair 26. The transport system control unit 201 controls the transport roller pair 24 and the transport roller pair 26 so that the length of the slack portion of the photographic paper 2 of the second slack unit 80 is maintained at a predetermined length F. During the exposure by the exposure unit 70, as described above, since the transport speed by the transport roller pair 24 is always maintained at a constant speed, only the transport roller pair 26 is controlled during this time. Will be.
[0129]
  Specifically, for example, when the paper sensor 82 detects that the length of the slack portion of the photographic paper 2 of the second slack portion 80 has increased to reach a predetermined length F, a predetermined time has elapsed from that point. Until the time elapses, the conveyance stop state by the conveyance roller pair 26 is continued. When a predetermined time elapses, the conveyance of the photographic paper 2 by the conveyance roller pair 26 is started. After that, when the paper sensor 82 detects that the length of the slack portion of the photographic paper 2 of the second slack portion 80 has decreased and has become less than the predetermined length F, until a predetermined time has elapsed from that point. The conveyance by the conveyance roller pair 26 is continued. When a predetermined time has elapsed, the conveyance of the photographic paper 2 by the conveyance roller pair 26 is stopped. By repeating such control of the conveying roller pair 26, the length of the slack portion of the photographic paper 2 of the second slack portion 80 is maintained substantially constant at a predetermined length F, and the exposure by the exposure unit 70 is performed. , The exposed photographic paper 2 is sequentially taken up in the take-up unit 100.
[0130]
<Operation of shutter 174>
  In the exposure unit 70, for example, when the photographic paper 2 passes through a position facing the exposure unit 70 without being exposed after the exposure of a plurality of last images of one order, the exposure of the next order image is performed thereafter. If the state is started as it is, a blank portion is formed between the last image of the previous order and the first image of the next order. Therefore, in such a case, the exposure by the exposure unit 70 is temporarily stopped, and the photographic paper 2 is rewound in the direction opposite to the previous conveyance direction by the conveyance roller pair 23 of the pre-exposure roller unit 60. At this time, the photographic paper 2 forming the slack portion in the second slack portion 80 is rewound by the conveying roller pair 23 and added to the slack portion of the photographic paper 2 in the first slack portion 60.
[0131]
  Further, when the photographic paper 2 is rewound in this way, the exposure by the exposure unit 70 is temporarily stopped, but at this time, from the blue SHG laser unit 71B, the green SHG laser unit 71G and the red LD 71R of the exposure unit 70. Operations such as emission of the laser beam and rotation of the polygon mirror 78 are stopped. Thereafter, when exposure by the exposure unit 70 is resumed, operations such as emission of laser light from the blue SHG laser unit 71B, green SHG laser unit 71G and red LD 71R of the exposure unit 70 and rotation of the polygon mirror 78 are resumed. The As a result, it is possible to prevent wasteful power consumption while exposure is not performed.
[0132]
  At this time, when the exposure operation in the exposure unit 70 is resumed, the modulation timing of the laser light emitted from the blue SHG laser unit 71B, the green SHG laser unit 71G, and the red LD 71R is adjusted again. Here, when adjusting the modulation timing of the laser beam, the shutter 174 is disposed at a position that closes the long hole 173 of the housing 70a in the optical path toward the photographic paper 2 of the laser beam deflected and scanned by the polygon mirror 78. Therefore, the optical path of the laser beam deflected and scanned by the polygon mirror 78 toward the photographic paper 2 is blocked. Then, after adjusting the modulation timing of the laser light, the shutter 174 is moved from the closed position to the open position, and exposure on the photographic paper 2 is resumed.
[0133]
<Conveying stop operation of the photographic paper 2 by the conveying roller pair 20>
  For example, when the exposure by the exposure unit 70 is interrupted, the conveyance of the photographic paper 2 may have to be stopped. At this time, the conveyance of the photographic paper 2 by the conveyance roller pair 20 that has been used to pull out the photographic paper 2 from the paper magazine 6 is stopped. Here, when the conveyance of the photographic paper 2 by the conveyance roller pair 20 is stopped, if the conveyance speed by the conveyance roller pair 20 is suddenly stopped (instantaneously becomes 0), the conveyance roller pair 20 is pulled. Accordingly, the rotating wound body 2a does not stop immediately, but continues to rotate further by its inertial force while gradually reducing the speed.
[0134]
  Therefore, after the conveyance roller pair 20 is stopped, the photographic paper 2 is unwound from the wound body 2a due to the inertial force of the wound body 2a. In particular, when the diameter of the wound body 2a stored in the paper magazine 6 is large, the inertial force of the wound body 2a also increases, so that the print is unwound from the wound body 2a by the inertial force of the wound body 2a. The length of the paper 2 is remarkably increased.
[0135]
  Here, the length of the photographic paper 2 unwound from the wound body 2a by the inertial force of the wound body 2a is the same as the wound body 2a and the transport roller when the dancer roller 12 of the adapter unit 10 is in the oscillation stable position. Even if the length of the transport path between the pair 20 is longer than the length of the transport path between the wound body 2a and the transport roller pair 20 when the dancer roller 12 of the adapter unit 10 is in the original position, When it is the same or shorter, the excess of the length can be absorbed by the dancer mechanism 16 of the adapter unit 10. For this reason, the photographic paper 2 is hardly loosened in the paper magazine 6.
[0136]
  On the other hand, the length of the photographic paper 2 unrolled from the wound body 2a by the inertial force of the wound body 2a is equal to the wound body 2a and the conveying roller pair 20 when the dancer roller 12 of the adapter unit 10 is in the original position. If it becomes longer than the length of the conveyance path between the two, the excess of the length cannot be absorbed by the dancer mechanism 16 of the adapter unit 10. For this reason, the photographic paper 2 is loosened in the paper magazine 6.
[0137]
  As described above, when the conveyance of the photographic paper 2 by the conveyance roller pair 20 is stopped in a state where the winding body 2a is rotating at a constant speed in the paper magazine 6, as described above, In order to prevent the photographic paper 2 from slackening, in the exposure apparatus 1 of the present embodiment, the conveyance system control unit 201 abruptly decreases the conveyance speed of the photographic paper 2 by the conveyance roller pair 20 to convey the conveyance roller pair 20. Is not stopped, but the conveyance roller pair 20 is controlled so that the conveyance speed of the photographic paper 2 by the conveyance roller pair 20 decreases stepwise.
[0138]
  In other words, for example, when the conveyance speed of the photographic paper 2 by the conveyance roller pair 20 is V3 before the conveyance of the photographic paper 2 by the conveyance roller pair 20 is stopped, first, the photographic paper by the conveyance roller pair 20 is first. 2 is transported at a transport speed V4 that is slower than V3 for a predetermined time. Thereafter, the conveyance roller pair 20 is controlled in two stages so that the conveyance speed of the photographic paper 2 by the conveyance roller pair 20 becomes zero. Note that the conveyance speed of the photographic paper 2 by the conveyance roller pair 20 may be decreased in multiple stages.
[0139]
  As a result, after the decrease in the conveyance speed of the conveyance roller pair 20 is started, the length of the photographic paper 2 unrolled from the winding body 2a by the inertial force of the winding body 2a is transferred to the dancer 16 of the dancer mechanism 16 of the adapter unit 10. It is possible to distribute without slacking between the front and rear of the roller 12 and the front and rear of the dancer roller 12 of the dancer unit 30.
[0140]
  Therefore, after the decrease in the conveyance speed of the conveyance roller pair 20 is started, absorption is performed by the dancer mechanism 16 of the adapter unit 10 in the length of the photographic paper 2 that is unrolled from the winding body 2a by the inertial force of the winding body 2a. Only a portion that is less than or equal to the possible length can be disposed upstream of the conveying roller pair 20. Then, on the upstream side of the conveyance roller pair 20, all of the photographic paper 2 that is unwound from the wound body 2 a by the inertial force of the wound body 2 a is not completely absorbed by the dancer mechanism 16 of the adapter unit 10, and the paper It is possible to prevent loosening in the magazine 6.
[0141]
  The length of each photographic paper 2 when the photographic paper 2 unwound from the wound body 2a by the inertial force of the wound body 2a is distributed to the upstream side of the conveying roller pair 20 and the downstream side of the conveying roller pair 20 The ratio differs depending on the method for reducing the conveyance speed of the photographic paper 2 by the conveyance roller pair 20. Therefore, for example, in consideration of the configuration of the dancer mechanism 16 of the adapter unit 10, that is, the length of the curved portion that can be formed by the dancer mechanism 16 (the length of the absorbable photographic paper 2), etc. It is preferable to appropriately reduce the conveyance speed of the paper 2.
[0142]
  Further, when the conveyance of the photographic paper 2 by the conveyance roller pair 20 is stopped in a state where the winding body 2 a is rotating at a constant speed in the paper magazine 6, the winding body 2 a is stopped in the paper magazine 6. At that time, the conveyance of the photographic paper 2 by the conveyance roller pair 20 is still continued, and after the winding body 2a is stopped in the paper magazine 6, the conveyance of the photographic paper 2 by the conveyance roller pair 20 is stopped. Is preferred.
[0143]
  Further, after the conveyance of the photographic paper 2 by the conveyance roller pair 20 is stopped, the conveyance of the photographic paper 2 by the conveyance roller pair 20 is resumed in a state where the wound body 2 a is stationary in the paper magazine 6. The transport system control unit 201 controls the transport roller pair 20 so that the transport speed of the printing paper 2 by the transport roller pair 20 increases stepwise. In the present embodiment, similarly to the control of the transport roller pair 15 of the adapter unit 10, first, the photographic paper 2 by the transport roller pair 20 is in a state where the wound body 2 a in the paper magazine 6 is stopped. The transport roller pair 20 is transported at a transport speed V0 that is relatively slow for a predetermined time, and thereafter the transport roller pair 20 is transported at a transport speed V1 that is faster than the transport speed V0. Controlled. The conveyance speed of the photographic paper 2 by the conveyance roller pair 20 may be increased in multiple stages.
[0144]
<Error detection of transport roller pair 21 and transport roller pair 24>
  As described above, the information adding unit control unit 206 controls the punch 52 to form an order mark on the photographic paper 2 so as to correspond to an image break for each order. It is also possible to recognize the formation time difference between one order mark and the next order mark.
[0145]
  The punch 52 of the information adding unit control unit 206 forms an order mark on the photographic paper 2 at a position where the conveyance speed is governed by the operation state of the conveyance roller pair 21. Accordingly, in the transport distance deriving unit 202, based on the difference in time between the formation of the two order marks and the drive signal supplied from the transport system control unit 201 to the motor 21a that drives the pair of transport rollers 21 between them, The conveyance distance of the photographic paper 2 by the conveyance roller pair 21 corresponding to the formation time difference is derived.
[0146]
  The mark sensor 96 detects an order mark formed on the photographic paper 2 at a position where the conveyance speed is governed by the operation state of the conveyance roller pair 24. Therefore, in the transport distance deriving unit 202, based on the difference in detection time between the two order marks by the mark sensor 96 and the drive signal supplied to the motor 24a that drives the transport roller pair 24 from the transport system control unit 201 between them. The conveyance distance of the photographic paper 2 by the conveyance roller pair 24 corresponding to the difference between the detection times of the two order marks is derived.
[0147]
  Then, the transport distance comparison unit 203 calculates the difference between the transport distance of the photographic paper 2 by the transport roller pair 21 and the transport distance of the photographic paper 2 by the transport roller pair 24 derived by the transport distance deriving unit 202. If the difference is greater than or equal to a predetermined value, the error notification unit 204 notifies the operator that a transport system error has occurred.
[0148]
  Here, as a problem that occurs in the transport roller pair 21 and the transport roller pair 24, for example, at least one of the transport roller pair 21 and the transport roller pair 24 slips between the photographic printing paper 2 and the transport roller pair 21. It is also conceivable that the roller diameter of the conveying roller pair 24 changes due to wear. In this case, the transport roller pair 21 and the transport roller pair 21 and the transport roller pair 24 are actually transported by the same distance as the transport distance corresponding to the drive signal supplied from the controller 200 to the motors 21a and 24a. It becomes impossible to convey by the roller pair 24, resulting in a conveyance system error.
[0149]
  From here, the detection procedure of the conveyance system error will be described with a specific example.
[0150]
(Specific example settings)
  Conveying speed of the photographic paper 2 by the conveying roller pair 21: speed s1
  Conveying speed of the photographic paper 2 by the conveying roller pair 24: speed s2
  Time difference between two order marks: Time t1
  Detection time difference between two order marks: time t2 or time t2 '
  Transport distance of photographic paper 2 by transport roller pair 21: distance L1
  Transport distance of photographic paper 2 by transport roller pair 24: distance L2 or distance L2 '
  Threshold value used for error detection in the error notification unit 204: threshold value X0 (where X0> 0)
[0151]
  First, a case where no trouble has occurred in either the transport roller pair 21 or the transport roller pair 24 (appropriate state) will be described.
[0152]
  In this case, the conveyance distance L1 of the photographic paper 2 by the conveyance roller pair 21 derived by the conveyance distance deriving unit 202 is the difference between the conveyance speed s1 of the photographic paper 2 by the conveyance roller pair 21 and the formation time of two order marks. Calculated by multiplying by t1.
  Distance L1 = speed s1 × time t1
Note that the conveyance distance of the photographic paper 2 by the actual conveyance roller pair 21 at this time is also the same as the distance L1.
[0153]
  Further, the transport distance L2 of the photographic paper 2 by the transport roller pair 24 derived by the transport distance deriving unit 202 is determined by the transport speed s2 of the photographic paper 2 by the transport roller pair 24 and the detection time difference t2 between the two order marks. Calculated by multiplying.
  Distance L2 = speed s2 × time t2
Note that the conveyance distance of the photographic paper 2 by the actual conveyance roller pair 24 at this time is also the same as the distance L2.
[0154]
  The transport distance comparison unit 203 calculates the difference between the transport distance L1 of the photographic paper 2 by the transport roller pair 21 and the transport distance L2 of the photographic paper 2 by the transport roller pair 24. The difference between the two is zero. (Both are consistent).
  Distance L2-Distance L1 = 0
Accordingly, since the difference between the two is smaller than the threshold value X0, the error notification unit 204 determines that no transport system error has occurred.
[0155]
  Next, for example, a description will be given of a case where no trouble has occurred in the transport roller pair 21 and a trouble has occurred in the transport roller pair 24. Here, as a failure of the transport roller pair 24, for example, slipping of the photographic paper 2 occurs, and the transport roller pair 24 can transport only a distance shorter than the transport distance corresponding to the drive signal supplied from the controller 200. Will be described.
[0156]
  In this case, the conveyance distance L1 of the photographic paper 2 by the conveyance roller pair 21 derived by the conveyance distance deriving unit 202 is the conveyance speed of the photographic paper 2 by the conveyance roller pair 21 as in the above-described proper state. It is calculated by multiplying s1 by the time difference t1 between the two order marks.
  Distance L1 = speed s1 × time t1
Note that the conveyance distance of the photographic paper 2 by the actual conveyance roller pair 21 at this time is also the same as the distance L1.
[0157]
  Further, the transport distance L2 ′ of the photographic paper 2 by the transport roller pair 24 derived by the transport distance deriving unit 202 is equal to the transport speed s2 of the photographic paper 2 by the transport roller pair 24 and the detection time difference t2 ′ between the two order marks. It is calculated by multiplying. Here, the detection time difference t2 ′ is actually longer than the detection time difference t2 because the transport roller pair 24 can transport only a distance shorter than the transport distance corresponding to the drive signal supplied from the controller 200. .
  Distance L2 '= speed s2 * time t2' (where time t2 '> time t2)
[0158]
  Then, the transport distance comparison unit 203 calculates the difference between the transport distance L1 of the photographic paper 2 by the transport roller pair 21 and the transport distance L2 ′ of the photographic paper 2 by the transport roller pair 24. Considering that the relationship of “speed s1 × time t1 = speed s2 × time t2” is established,
Distance L2'-distance L1 = (speed s2 * time t2 ')-(speed s1 * time t1)
                      = Speed s2 × (time t2′−time t2)
Thus, since the time t2 'is longer than the time t2, the difference between the two does not become zero. Therefore, when the difference between the two is larger than the threshold value X0, the error notification unit 204 determines that a transport system error has occurred.
[0159]
  In the same manner as described above, when at least one of the transport roller pair 21 and the transport roller pair 24 is defective, the error notification unit 204 can determine that a transport system error has occurred. .
[0160]
<Operation when the trailing edge of the photographic paper 2 is detected by the paper sensor 93>
  When the trailing edge of the long photographic paper 2 is detected by the paper sensor 93 by the conveyance of the photographic paper 2 through the dancer unit 30, the upstream side of the guide roller 31 is upstream of the guide roller 31. The force to fasten the photographic paper 2 on the side is hardly applied. Accordingly, at this time, the upward force from the photographic paper 2 is not applied to the dancer roller 32. Therefore, when the dancer roller 32 pushes down the photographic paper 2 between the guide roller 31 and the guide roller 33 by its own weight, The dancer roller 32 falls as it is.
[0161]
  As described above, when the dancer roller 32 is dropped as it is, the holding members 34 and 35 holding the dancer roller 32 come into contact with the coil springs 44 and 45 disposed above the moving members 42 and 43, so that the dancer roller 32. Is gradually reduced.
[0162]
  Here, in the present embodiment, when the rear end of the long photographic paper 2 is detected by the paper sensor 93 in preparation for the dancer roller 32 falling due to its own weight, the dancer roller 32 is The dancer control unit 205 drives the driving mechanism 48 so that the moving members 42 and 43 are brought into contact with the lower surfaces of the holding members 34 and 35 or just below the lower surface so as not to move below the predetermined height. It is designed to move to a position.
[0163]
  As described above, in the transport device 8 included in the exposure apparatus 1 of the present embodiment, the dancer unit 30 is provided between the transport roller pair 20 and the transport roller pair 21, and the guide roller pair of the dancer unit 30 is provided. When the dancer roller 32 urged downward by its own weight moves between the pair 31 and the guide roller 32 pair, both ends of the dancer roller 32 are moved to the dancer roller 32.So that no gap is formed between the outer peripheral surface of the paper and the photographic paper 2Since it is held by the holding members 34 and 35 so that it can be freely displaced in the vertical direction, the force from the dancer roller 32 can be evenly applied to the photographic paper 2 in the width direction. Therefore, by controlling the transport roller pair 20 and the transport roller pair 21, respectively, the length of the photographic paper 2 of the dancer unit 30 can be more accurately controlled, and the dancer roller 32 can be equally applied to the photographic paper 2. This prevents the photosensitive medium from being twisted or meandering due to the fact that no excessive force is applied.
[0164]
  In addition, since the dancer roller 32 is a roller that is held by the holding members 34 and 35 so as to be rotatable about the axis, the dancer roller 32 is easy to roll with respect to the photographic paper 2, and the dancer roller 32 is photographic paper. It is possible to suppress the photographic paper 2 from being damaged by being in contact with 2.
[0165]
  Further, since the holding members 34 and 35 can move together with the dancer roller 32 in the vertical direction, which is the movement direction of the dancer roller 32, the dancer roller 32 is held while its movement path is restricted by the holding member that does not move therewith. The dancer roller 32 can be stably held by the holding members 34 and 35 as compared with the case where the dancer roller 32 is provided.
[0166]
  The dancer unit 30 is provided with sensors 41 a to 41 d for detecting the position of the holding member 34, and the photographic paper 2 between the guide roller 31 and the guide roller 33 based on the position of the holding member 34. It is possible to detect the length of the curved portion. Accordingly, the conveyance roller pair 20 and the conveyance roller pair 21 can be controlled so that the length of the curved portion of the photographic paper 2 of the dancer unit 30 is always a certain length or more. It becomes possible to separate from the conveyance of the photosensitive medium by the roller pair 20.
[0167]
  In addition, the sensors 41a to 41d are arranged apart from each other along the moving direction of the holding member 34, and the distance between them and the vertical height of the holding member 34 are substantially the same. 34 is always detected by only one of the sensors 41a-41d. Therefore, the position of the dancer roller 32 can always be grasped by the sensors 41a to 41d.
[0168]
  The holding members 34 and 35 are provided with guide members 38 having surfaces facing each other across the conveyance path of the photographic paper 2 below the dancer roller 32, and the dancer roller 32 and the guide member 38 are spaced apart from each other by a predetermined distance. It is possible to move together while maintaining a separated state. Therefore, when the leading end of the photographic paper 2 is conveyed between the guide roller 31 and the guide roller 33, the leading end of the photographic paper 2 can be reliably guided from the guide roller 31 to the guide roller 33. it can.
[0169]
  Further, the holding member 35 is movable in the width direction of the photographic paper 2 when moving in the vertical direction along the shaft 37. Accordingly, when the holding members 34 and 35 that hold the dancer roller 32 move in the vertical direction along the shafts 36 and 37, the holding members 34 and 35 move even if the dancer roller 32 is largely inclined in the axial direction. It can be suppressed that it becomes impossible.
[0170]
  Further, on the shafts 36 and 37, coil springs 44 and 45 are arranged between the holding members 34 and 35 and the moving members 42 and 43, respectively. Further, when the rear end of the long photographic paper 2 is detected by the paper sensor 93, the dancer roller 32 is not moved further below the predetermined height by a predetermined height. The unit controller 205 moves the moving members 42 and 43 upward by driving the drive mechanism 48. Accordingly, when the trailing edge of the photographic paper 2 passes between the guide roller 31 and the guide roller 33, or when the photographic paper 2 is cut at a position other than between the guide roller 31 and the guide roller 33, the guidance is performed. Even when the force applied to the dancer roller 32 from the photographic paper 2 between the roller 31 and the guide roller 33 is smaller than the weight of the dancer roller 32, the dancer roller 32 falls and the member provided below the dancer roller 32 has a large force. It is possible to suppress a collision at a speed. Therefore, the dancer roller 32 or its peripheral members can be prevented from being damaged.
[0171]
  The preferred embodiment of the present invention has been described above. However, the present invention is not limited to the above-described embodiment, and various design changes can be made as long as they are described in the claims. It is a thing. For example, in the above-described embodiment, the dancer roller 32, which is a roller held by the holding members 34 and 35 so as to be rotatable about the axis, moves while abutting against the photographic paper 2 between the guide roller 31 and the guide roller 33. Although the case where it is possible is described, the shape of the member (contact member) that can move in the vertical direction while contacting the photographic paper 2 between the guide roller 31 and the guide roller 33 is not limited to this. , It is not necessarily a roller.
[0172]
  Moreover, although the above-mentioned embodiment demonstrated the case where the holding members 34 and 35 were movable with the dancer roller 32 to the up-down direction which is a movement direction of the dancer roller 32, it is not restricted to this, It is not necessarily a holding member. May not be movable together with the dancer roller 32 in the vertical direction, which is the direction of movement of the dancer roller 32. Therefore, in the present embodiment, the dancer roller 32 may be directly held by the shafts 36 and 37 so as to be movable in the vertical direction. In this case, the shafts 36 and 37 function as a holding member for the dancer roller 32. Will have.
[0173]
  In the above-described embodiment, the dancer unit 30 is provided with sensors 41 a to 41 d for detecting the position of the holding member 34, and the photographic paper 2 of the dancer unit 30 is based on the position of the holding member 34. The case where the length of the curved portion can be detected has been described. However, the present invention is not limited to this, and when it is not necessary to detect the length of the curved portion of the photographic paper 2 of the dancer unit 30, the dancer unit 30. There may be no sensor for detecting the position of the holding member 34. Further, even when the sensors are arranged, it is not always necessary to arrange a plurality of sensors, and the sensors are arranged apart from each other along the moving direction of the holding member 34. The height in the vertical direction may not be substantially the same.
[0174]
  Further, in the above-described embodiment, the guide member 38 having a surface opposed to the dancer roller 32 with the conveyance path of the photographic paper 2 sandwiched between the dancer roller 32 and the dancer roller 32 is maintained at a predetermined distance. While the case where it is attached to the holding members 34 and 35 so as to be movable together with the dancer roller 32 is explained, the configuration of the guide member is not limited to this, and the leading end portion of the photographic paper 2 is the guide roller 31 and the guide roller. The photographic paper 2 can be properly guided from the guide roller 31 to the guide roller 33 when being conveyed between the photographic paper 33 and the leading edge of the photographic paper 2 is guided by the guide roller 31 and the guide roller 33. As long as the curved portion of the photographic paper 2 can be formed between the guide roller 31 and the guide roller 33 when the sheet is not conveyed between the guide roller 31 and the guide roller 33, any change can be made.
[0175]
  Further, in the above-described embodiment, the case where the holding member 35 is movable in the width direction of the photographic paper 2 when moving in the vertical direction along the shaft 37 has been described. Is not movable in the width direction of the photographic paper 2 when moving in the vertical direction along the shaft 37.
[0176]
  In the above-described embodiment, the coil springs 44 and 45 having the cushion function are arranged on the shafts 36 and 37 between the holding members 34 and 35 and the moving members 42 and 43, respectively. The member having may not be arranged. Moreover, even if the member which has a cushion function is arrange | positioned, what is necessary is just to have the function similar to a coil spring.
[0177]
  Further, in the above-described embodiment, when the rear end portion of the long photographic paper 2 is detected by the paper sensor 93, the dancer roller 32 is then further below the predetermined height by a predetermined height or more. Although the case where the moving members 42 and 43 are moved upward so as not to move has been described, the moving members 42 and 43 need not necessarily be moved in this way.
[0178]
  In the above-described embodiment, in the dancer unit 30, the predetermined distance between the sensors 41a to 41d that can detect the position of the holding member 34 is substantially the same as the height of the holding member 34 (the length in the moving direction). However, the present invention is not limited to this, and the predetermined distance between the sensors 41 a to 41 d may be shorter than the height of the holding member 34. The sensors 41 a to 41 d that can detect the position of the holding member 34 are not necessarily provided, and a sensor that can detect the position of the dancer roller 32 may be provided.
[0179]
  Moreover, although the above-mentioned embodiment demonstrates the case where it is in the dancer part 30 and the dancer roller 32 can move to an up-down direction (vertical direction), it is not restricted to this, A dancer roller (contact member) Need only be movable in the direction in which the length of the curved portion of the photographic paper 2 in the dancer section 30 changes. Therefore, for example, the dancer roller may be movable in the horizontal direction or may be movable in an oblique direction. However, in this case, it is necessary to separately provide a member for biasing the dancer roller in that direction.
[0180]
  Further, in the above-described embodiment, after the exposed photographic paper 2 is taken up by the take-up unit 100 mounted on the downstream side of the transport device 8 of the exposure apparatus 1, the take-up unit 100 is separately provided. Although the case where the development processing of the photographic paper 2 that has been exposed by being mounted on the processor as the development processing apparatus is performed has been described, the present invention is not limited to this, and a processor is provided on the downstream side of the transport device 8 so as to be exposed. The photographic paper 2 may be supplied directly from the transport device 8 to the processor.
[0181]
  In the above-described embodiment, the transport device 8 included in the exposure apparatus 1 has been described. However, the present invention is not limited to this, and any transport device that transports a photosensitive medium may be transported included in devices other than the exposure device. Similar effects can be obtained in the apparatus.
[0182]
【The invention's effect】
  As described above, according to the first aspect, the contact member urged in the direction of increasing the length of the photosensitive medium between the first roller pair and the second roller pair is the first roller. When the photosensitive medium moves in a direction in which the length of the photosensitive medium between the pair and the second roller pair changes, both ends of the contact member areDo not create a gap between the outer peripheral surface of the contact member and the photosensitive mediumSince it is held by the holding member so as to be freely displaceable, a force from the contact member can be uniformly applied to the photosensitive medium in the width direction. Therefore, the length of the photosensitive medium between the first roller pair and the second roller pair can be controlled more accurately by controlling the first roller pair and the second roller pair, respectively. At the same time, the photosensitive medium is less likely to twist or meander due to the fact that an equal force is not applied from the contact member to the photosensitive medium.
  In addition, for example, the abutting member can be stably held by the holding member as compared with a case where the abutting member is held while the moving path is regulated by the holding member that does not move with the abutting member.
[0183]
  According to the second aspect, the contact member can easily roll with respect to the photosensitive medium, and the damage of the photosensitive medium due to the contact member contacting the photosensitive medium can be suppressed. This is particularly effective when the contact member contacts the photosensitive surface of the photosensitive medium.
[0184]
[0185]
  Claim3According to this, the first and second roller pairs can be controlled so that the length of the photosensitive medium between the first roller pair and the second roller pair is always equal to or greater than a certain value. The conveyance of the photosensitive medium by the roller pair can be separated from the conveyance of the photosensitive medium by the first roller pair.
[0186]
  Claim4According to this, the position of the contact member can always be grasped by the sensor.
[0187]
  Claim5According to the above, when the front end portion of the photosensitive medium is conveyed between the first roller pair and the second roller pair disposed on the downstream side of the contact member, the front end portion of the photosensitive medium is moved to the first roller. It is possible to reliably guide the pair until reaching the second roller pair.
[0188]
  Claim6According to the present invention, when the first holding member and the second holding member move together with the contact member while maintaining a constant distance therebetween, even if the contact member is largely inclined in the axial direction, It can be suppressed that the first holding member and the second holding member cannot move.
[0189]
  Claim7According to the present invention, when the rear end portion of the photosensitive medium passes between the first roller pair and the second roller pair, or at a position other than between the first roller pair and the second roller pair. Even when the force applied to the contact member from the photosensitive medium between the first roller pair and the second roller pair is smaller than the urging force against the contact member by cutting The abutting member collides with a member provided in the moving direction at a high speed by moving according to the biasing force in the direction of increasing the length of the photosensitive medium between the first roller pair and the second roller pair. Can be suppressed. Therefore, the contact member or its peripheral members can be prevented from being damaged.
[0190]
  Claim8According to the present invention, when the rear end portion of the photosensitive medium passes between the first roller pair and the second roller pair, or at a position other than between the first roller pair and the second roller pair. Even when the force applied to the contact member from the photosensitive medium between the first roller pair and the second roller pair is smaller than the urging force against the contact member by cutting The abutting member collides with a member provided in the moving direction at a high speed by moving according to the biasing force in the direction of increasing the length of the photosensitive medium between the first roller pair and the second roller pair. Can be suppressed. Therefore, the contact member or its peripheral members can be prevented from being damaged.
[Brief description of the drawings]
FIG. 1 is a view showing a schematic configuration of an exposure apparatus including a transport apparatus according to an embodiment of the present invention.
FIG. 2 is a front view showing a schematic configuration of an adapter unit.
FIG. 3 is a side view showing a schematic configuration of a dancer unit.
FIG. 4 is a cross-sectional view showing a schematic configuration of a dancer unit.
FIG. 5 is a diagram for explaining a configuration in which a holding member holds a dancer roller.
FIG. 6 is a top view showing a schematic configuration of a dancer unit.
7 is an enlarged view of range A and range B of FIG.
FIG. 8 is a top view showing a schematic configuration of an exposure unit.
FIG. 9 is a partial side view showing a schematic configuration of an exposure unit.
FIG. 10 is a simplified block diagram of the main part of the controller of the exposure apparatus.
[Explanation of symbols]
1 Exposure equipment
2 photographic paper (photosensitive medium)
5 Paper magazine
8. Conveying device (photosensitive medium conveying device)
10 Adapter section
15 Transport roller pair
16 Dancer mechanism
20 Conveying roller pair (first roller pair)
21 Conveying roller pair (second roller pair)
24 Conveying roller pair
26 Transport roller pair (third roller pair)
30 Dancer club
32 Dancer roller (contact member; roller)
34, 35 Holding member(No.1 holding member; second holding member)
38 Guide member
41a to 41d sensors (position detecting means)
42, 43 Movement member (movement prohibition means)
44, 45 Coil spring (cushion member)
48 Drive mechanism (movement prohibition means)
50 Image information adding section
52 Punch
60 Loop before exposure
70 exposure unit
80 Loop after exposure
93 Paper sensor (rear end detection sensor)
96 Mark sensor
200 controller
201 Conveyance system controller
202 Conveyance distance deriving unit
203 Conveyance distance comparison unit
204 Error notification section
205 Dancer control unit
206 Information adding unit control unit
207 Exposure unit controller
208 Sensor Management Department

Claims (8)

A first pair of rollers that sandwich a long photosensitive medium and convey it downstream;
A second roller pair that sandwiches the photosensitive medium downstream of the first roller pair and conveys the photosensitive medium further downstream;
A direction in which the length of the photosensitive medium changes between the first roller pair and the second roller pair by contacting the photosensitive medium between the first roller pair and the second roller pair. A contact member biased in a direction to increase the length of the photosensitive medium between the first roller pair and the second roller pair;
Both end portions of the abutment member for the width direction of the photosensitive medium is retained in the state where the displaceable freely so that a gap is not formed between the outer peripheral surface and the photosensitive medium of the abutment member, and, the through hole And a holding member that is movable along with the abutting member along a shaft that is inserted into the photosensitive medium conveying device.   2. The photosensitive medium carrying device according to claim 1, wherein the contact member is a roller held by the holding member so as to be rotatable about an axis. 3. The photosensitive medium carrying device according to claim 1, further comprising position detecting means for detecting the position of the contact member. The position detecting means includes a plurality of sensors arranged apart from each other along the moving direction of the contact member;
A length along the moving direction of the plurality of gap between the abutment member or the holding member of the sensor, the contact member and the holding member is detected at all times by some of the sensors in the plurality of sensors 4. The photosensitive medium carrying device according to claim 3 , wherein the relationship is set as described above. Guiding said abutment moving direction and the second pair of rollers the leading edge from the first pair of rollers and the contact member co to move possible a photosensitive medium having a plane perpendicular member photosensitive medium conveying device according to any one of claims 1 to 4, characterized by further comprising a guide member. The holding member includes a first holding member and a second holding member for holding the contact member at each of both end portions in the width direction of the photosensitive medium,
Photosensitive medium conveying device according to any one of claims 1 to 5, characterized in that at least one of said first and second holding members can be displaced in the width direction of the photosensitive medium. The moving speed is gradually reduced by contacting the abutting member that moves beyond a predetermined position in the direction of increasing the length of the photosensitive medium between the first roller pair and the second roller pair. photosensitive medium conveying device according to any one of claims 1 to 6, characterized in that it further comprises a cushion member. A rear end detection sensor for detecting the rear end of the photosensitive medium on the upstream side of the first roller pair;
A direction in which the contact member increases the length of the photosensitive medium between the first roller pair and the second roller pair after the rear end detection sensor detects the rear end of the photosensitive medium. photosensitive medium conveying device according to any one of claims 1 to 7, characterized by further comprising a movement inhibiting means for inhibiting the movement beyond a predetermined position.

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