JP2018144923A - Printing apparatus and sheet processing method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a printing apparatus capable of performing normal processing on both sides of a sheet while stably conveying the sheet irrespective of size of the sheet.SOLUTION: A printing apparatus 1 comprises a pair of first conveyance rollers 5 arranged upstream of a print head, a pair of second conveyance rollers 8 arranged downstream therein, and a pair of third conveyance rollers 110 arranged more downstream than the pair of second conveyance rollers 8. Then, conveying force of the pair of third conveyance rollers 110 is made to differ between when a sheet S at the pair of third conveyance rollers 110 is nipped by the pair of first conveyance rollers 5 through the pair of second conveyance rollers 8 and when the sheet is nipped by the pair of first conveyance rollers 5 without passing through the pair of second conveyance rollers 8.SELECTED DRAWING: Figure 4

Description

  The present invention relates to a printing apparatus for performing processing on both sides of a sheet.

  Patent Document 1 discloses an ink jet recording apparatus that records images on both sides of a sheet. According to the ink jet recording apparatus of Patent Document 1, printing on the front surface, reversing the front and back surfaces, printing on the back surface, and discharging the supplied sheet while rotating the four sets of driving rollers in the forward direction or the reverse direction. These steps are performed in this order.

JP 2012-152915 A

  However, in general, the plurality of drive rollers arranged in the sheet conveyance path are commonly controlled by the same motor. For this reason, in the configuration of Patent Document 1, when double-sided printing is performed on a relatively large size sheet, there is a situation in which a print process is performed on another area of the sheet while the sheet is pulled back into the apparatus, and the sheet counters the rotation of the roller. In some cases, there were places that proceeded. As a result, excessive tension was applied to the sheet, which could damage the sheet or prevent normal printing.

  The present invention has been made to solve the above problems. Accordingly, an object of the present invention is to provide a printing apparatus capable of performing normal processing on both sides of a sheet while stably conveying the sheet regardless of the size of the sheet.

  To this end, the present invention provides a print head for printing on a conveyed sheet, a first conveyance roller pair that is arranged upstream of the print head in the conveyance direction and conveys the sheet while nipping it, A second conveying roller pair that is disposed downstream of the print head in the conveying direction and conveys the sheet while nipping the sheet, and is disposed further downstream than the second conveying roller pair in the conveying direction; A first conveying path for guiding the sheet in the order of the first conveying roller pair, the second conveying roller pair, and the third conveying roller pair; A second conveyance path for guiding a sheet from the third conveyance roller pair to the first conveyance roller pair without passing through the second conveyance roller pair; and the first roller pair. And a driving source that rotates the second roller pair and the third roller pair in common in either the transport direction or the direction opposite to the transport direction. When the sheet in the vicinity of the third transport roller pair is nipped by the first transport roller pair through the first transport path, and in the vicinity of the third transport roller pair Is characterized in that the conveying force of the third conveying roller pair is made different from when nipped by the first conveying roller pair through the second conveying path.

  According to the present invention, it is possible to perform normal processing on both sides of a sheet while stably conveying the sheet regardless of the size of the sheet.

Configuration diagram of printing device Block diagram showing configuration of control in printing apparatus Diagram for explaining the layout of a plurality of transport rollers in detail Flowchart for explaining processing steps for executing double-sided printing The figure which shows the conveyance state of the sheet | seat of 1st Embodiment. The figure which shows the conveyance state of the sheet | seat of 1st Embodiment. The figure which shows the conveyance state of the sheet | seat of 1st Embodiment. The figure which shows the conveyance state of the sheet | seat of 1st Embodiment. The figure which shows the conveyance state of the sheet | seat of 1st Embodiment. The figure which shows the conveyance state of the sheet | seat of 1st Embodiment. The figure which shows the structure which changes nip force in 2nd Embodiment. The figure which shows the structure which transmits conveyance force in 3rd Embodiment. The figure which shows the structure which changes a conveyance direction in 3rd Embodiment. The figure which shows the structure which changes conveyance force in 3rd Embodiment.

(First embodiment)
FIG. 1 is a configuration diagram of a printing apparatus according to an embodiment of the present invention. In the printing apparatus 1, the sheets S stacked in the cassette 21 are supplied one by one into the apparatus, and after images are printed in order on the front surface (first surface) and the back surface (second surface), they are discharged to the outside. The The cassette 21 stacks and stores unprocessed sheets. When a print command is input, the pickup roller unit 22 is operated, and the pickup roller 22a disposed at the leading end rotates in the clockwise direction in the drawing while contacting the surface of the uppermost sheet in the cassette 21. As a result, the sheet S advances in the −Y direction and comes into contact with the separation unit 23, and only the uppermost sheet S rises along the inner wall of the separation unit 23. Then, it passes through the curved path 3 formed by the curved guide 31 and the back curved guide 32 and is nipped by the first conveying roller pair 5. Immediately before the first conveying roller pair 5, a sheet sensor 4 for detecting the presence or absence of the sheet S and the passage of the leading and trailing ends is provided.

  The first conveying roller pair 5 includes a first conveying roller 52 and a pinch roller 51 that follows the first conveying roller 52. The first transport roller 52 is provided with a rotary encoder 53 for detecting the rotation amount, that is, the transport amount of the sheet S. As the first conveying roller 52 rotates counterclockwise, the sheet S nipped by the first conveying roller pair 5 advances in the + Y direction and reaches the nip portion of the second conveying roller pair 8. The second conveying roller pair 8 includes a second conveying roller 81 and a spur 82 that is driven by the second conveying roller 81, and the sheet S with a smaller nip force than the first conveying roller pair 5 together with the first conveying roller pair 5. Transport.

  A print unit 7 is disposed above the sheet S between the first conveyance roller pair 5 and the second conveyance roller pair 8. The print unit 7 includes a carriage 71 that can reciprocate in the X direction in the figure, and a print head 72 that is mounted on the carriage 71 and prints an image on the surface of the sheet S. In this embodiment, the print head 72 is an inkjet print head, and a plurality of print elements capable of ejecting ink are arranged in the Y direction. With such a configuration, the main scanning in which the print head 72 ejects ink while the carriage 71 moves in the X direction, and the conveyance operation in which the first and second conveyance roller pairs convey the sheet in the Y direction are performed. By repeating alternately, an image is formed on the sheet S step by step. The back surface of the sheet S facing the print unit 7 is supported by the platen 6, and the print head 72 and the surface of the sheet S are maintained at a certain distance. Although a serial type print head is illustrated here, a full line type print head in which a plurality of print elements are arranged in the width direction of the sheet S may be used.

  A lower surface guide 94 that supports the lower surface side of the sheet S and a duplex switching flapper 9 are disposed on the downstream side of the second conveying roller pair 8. The double-sided switching flapper 9 has a configuration in which a flap 92 having a convex portion on the lower side rotates around a rotation shaft 91, and a spur-like auxiliary roller 93 is attached to the convex portion of the flap 92. When the sheet is not being conveyed, the double-side switching flapper 9 tries to rotate below the rotating shaft 91 by its own weight, but the auxiliary roller 93 abuts the lower surface guide 94 to maintain the posture as shown in the figure. doing. The sheet S conveyed by the second conveying roller pair 8 advances along the lower surface guide 94, pushes up the double-side switching flapper 9, and further advances in the Y direction while rotating the auxiliary roller 93. The auxiliary roller 93 may be urged in the −Z direction by an elastic member such as a spring.

  A discharge unit 10 is disposed further downstream of the double-sided switching flapper 9. The discharge unit 10 mainly includes a third conveyance roller pair 110 including a third conveyance roller 101 and a spur 102, a spur holder 103 that supports the spur 102, and a spur holder frame that rotatably supports the spur holder 103. 108.

  The box-shaped spur holder frame 108 is fixed in the apparatus so as to cover the third transport roller pair 110 from above, and at a position upstream of the third transport roller pair 110, the spur holder rotating shaft. A spur holder 103 is rotatably supported via 104. Further, at a position downstream of the third conveying roller pair 110 of the spur holder frame 108, an elliptical pressure release cam 105 is rotatably supported via a pressure release cam rotating shaft 106.

  The spur holder 103 that supports the spur 102 extends in the downstream direction to a position where the spur holder 103 can come into contact with the pressure release cam 105, and the rotation position of the spur holder 103 is changed according to the rotation position of the pressure release cam 105. Is done. On the other hand, a spur pressure spring 107 is disposed between the spur holder frame 108 and the spur holder 103 in the Z direction, and urges the spur 102 toward the third transport roller 101. Based on the above configuration, ON / OFF of the nip of the third conveying roller pair 110 is switched depending on the rotational position of the pressure release cam 105.

  In the case of single-sided printing or in the case of double-sided printing, when the printing process for the first side and the second side is completed, the third transport roller 101 rotates clockwise in the drawing to discharge the sheet S in the Y direction. Such a path for guiding the sheet S in the order of the first transport roller pair, the second transport roller pair, and the third transport roller pair is referred to as a first transport path. On the other hand, when the single-sided printing process still remains in the double-sided printing, the third transport roller 101 rotates counterclockwise and pulls the sheet S back into the apparatus.

  A reversing path 11 serving as a second transport path is disposed below the first transport roller pair 5, the print unit 7, and the second transport roller pair 8. The reverse path 11 includes an upper guide 111 and a lower guide 112 extending in the Y direction, and a fourth transport roller pair 115 disposed in the middle of the path. The fourth transport roller pair 115 is a reverse transport roller 113. And a reverse driven roller 114. The reverse conveying roller 113 of this embodiment is not driven when the third conveying roller 101 rotates clockwise, and counterclockwise in synchronization with the third conveying roller 101 when rotating counterclockwise. It is designed to rotate. For this reason, the sheet S pulled back by the third conveyance roller pair 110 enters the reversal path 11 through the branch port 109, is conveyed by the fourth conveyance roller pair 115, and then enters the curved path 3 from the junction port 33. Join and head to the print processing department.

  The first transport roller 52, the second transport roller 81, the third transport roller 101, and the reverse transport roller 113 described above are connected by a mechanism (not shown) and are rotated in the same direction by a common drive source. ing.

  FIG. 2 is a block diagram illustrating a control configuration in the printing apparatus 1. The MPU 201 controls the entire apparatus according to the program and parameters stored in the ROM 201 while using the RAM 203 as a work area. For example, when a print command is input from the externally connected host computer 214 via the I / F, the MPU 201 develops the received image data in the RAM 203. Then, predetermined image processing is performed according to programs and parameters stored in the ROM 201, and print data that can be printed by the print head 72 is generated.

  The head driver 207 drives the print head 72 according to the print data expanded in the RAM 203 under the instruction of the MPU 201. The carriage motor driver 208 drives the carriage motor 204 under the instruction of the MPU 201 to reciprocate the carriage 71 at a predetermined speed.

  The transport motor driver 209 drives the transport motor 205 under the instruction of the MPU 201 and drives the first transport roller 52, the second transport roller 81, the third transport roller 101, and the reverse transport roller 113 in the forward direction or the reverse direction. To do. At this time, the MPU 201 determines the conveyance state of the sheet S, the timing when the leading and trailing ends have passed, and the like based on the detection result of the sheet sensor 4. Further, the rotation amount of the first conveyance roller 52 and the conveyance distance of the sheet S are acquired based on the detection result of the rotary encoder 53. That is, the MPU 201 can control the conveyance of the sheet S by driving the conveyance motor driver 209 based on these detection results.

  The feed motor driver 210 controls the pickup roller unit 22 by driving the feed motor 206 under the instruction of the MPU 201. The nip adjustment motor driver 212 drives the nip adjustment motor 211 under the instruction of the MPU 201 to rotate the pressure release cam 105.

  FIG. 3 is a diagram for explaining the layout of a plurality of transport rollers in detail. In the figure, the conveyance path from the contact point P1 by the pickup roller 22a to the nip portion P2 of the first conveyance roller pair 5 is L1, and the nip of the third conveyance roller pair 110 is from the nip portion P2 of the first conveyance roller pair 5. The distance to the part P3 is indicated by L3. A distance from the sheet sensor 4 to the nip portion P3 of the third transport roller pair 110 is indicated by L2. In the present embodiment, these distances satisfy the relationship (L3 <L2 <L1).

  Generally, in order to perform stable conveyance, it is desirable that the sheet S being conveyed is nipped by at least two pairs of conveyance rollers. For this reason, the printing apparatus 1 according to the present embodiment is designed such that L1 having the longest nip distance is shorter than the minimum sheet size handled by the printing apparatus 1. Specifically, the minimum sheet size that can be handled by the printing apparatus 1 is the photograph L size (89 mm × 127 mm), and the transport path L1 is (127−α) mm in consideration of the margin α.

  Under such a configuration, the rear end of the sheet S passes through the sheet sensor 4 with the front end of the sheet S being nipped by the third roller pair 110 regardless of the size of the sheet. To do. The MPU 201 can predict the timing at which the trailing edge reaches the third conveyance roller pair 110 based on the timing at which the sheet sensor 4 detects the trailing edge of the sheet S.

  FIG. 4 is a flowchart for explaining processing steps executed by the MPU 201 when a duplex printing command is input to the printing apparatus 1. When this process is started, the MPU 201 first executes a feeding operation in step S101. Specifically, the feeding motor 206 is driven via the feeding motor driver 210, and the pickup roller 22a is rotated by an amount sufficient for the uppermost sheet in the cassette 21 to reach the sheet sensor 4.

  In step S102, the MPU 201 determines whether the detection result of the sheet sensor 4 is ON. FIG. 5 shows a state in which the front end T of the first surface of the sheet S reaches the first conveying roller pair 5 through the sheet sensor 4. In such a state, the sheet sensor 4 detects the leading edge of the sheet S, and the MPU 201 proceeds to step S103. On the other hand, if the detection result of the sheet sensor 4 is not ON in step S102, the MPU 201 determines that the feeding of the sheet S has failed, jumps to step S114, stops the printing operation, and ends this processing. To do.

  In the present embodiment, when the feed motor 206 rotates the pickup roller 22a in the sheet feeding direction (clockwise direction), the first transport roller 52 rotates in the direction opposite to the transport (clockwise direction). It is supposed to be. For this reason, the sheet S is not conveyed downstream from the first conveying roller pair 5 while the pickup roller 22 a is rotating. That is, the sheet sensor 4 can be positioned (registered) by driving the feeding motor 206 for a while after the sheet sensor 4 detects the leading edge of the sheet S.

  In step S103, the MPU 201 executes a printing operation for the first surface. Specifically, first, the feeding motor 206 is stopped, the conveyance motor 205 is driven while checking the count value of the rotary encoder 53, and the top of the image is aligned with the print head 72. Then, main scanning for moving the carriage 71 in the X direction at a predetermined speed while ejecting ink from the print head 72 according to the print data, and transport for transporting the sheet S in the Y direction by a distance corresponding to the print width of the print head 72. The operation is repeated alternately.

  FIG. 6 is a diagram illustrating a sheet conveyance state during the printing operation on the first surface in step S103. By alternately repeating the main scanning and the conveying operation as described above, the sheet S gradually advances in the Y direction, the leading edge T of the first surface passes through the second conveying roller pair 8, and pushes up the duplex switching flapper 9. Then, it proceeds on the lower surface guide 94 toward the discharge unit 10. At this time, the auxiliary roller 93 of the double-sided switching flapper 9 rotates as the sheet S advances while contacting the first printed surface.

  In step S103, when the first surface rear end E has not reached the sheet sensor 4 at the time when printing of the first surface is completed, the MPU 201 determines that the rear side of the first surface of the sheet S is in accordance with the image size and the sheet size. The sheet S is conveyed to a position where the end E passes the sheet sensor 4.

  In step S <b> 104, the MPU 201 determines whether the first surface rear end E of the sheet S has passed the sheet sensor 4. If the rear end E of the first surface is not detected, it is determined that the conveyance is defective, and the process jumps to step S114. On the other hand, if the first surface rear end E is detected, the process proceeds to step S105.

  In step S <b> 105, the MPU 201 conveys the sheet S to a position where the first surface rear end E of the sheet S passes the duplex switching flapper 9. Specifically, the conveyance motor 205 is driven while checking the rotary encoder 53, and the sheet S is conveyed by a distance slightly shorter than L2 from the position where the first surface rear end E is detected by the sheet sensor 4. At this time, as described above, the first conveyance roller 52, the second conveyance roller 81, and the third conveyance roller 101 are configured to be linked to each other. For this reason, the conveyance distance of the sheet S is controlled based on the output value of the rotary encoder 53 that detects the rotation of the first conveyance roller 52 even after the first surface rear end E passes through the first conveyance roller pair 5. I can do it.

  FIG. 7 shows a state in which the transport process in step S105 has been completed. The rear end E of the first surface passes through the duplex switching flapper 9 and is nipped by the third conveyance roller pair 110.

  In step S <b> 106, the MPU 201 reversely rotates the transport motor 205 via the transport motor driver 209. As a result, the third conveying roller 101 that nips the vicinity of the rear end E of the first surface of the sheet S rotates counterclockwise, and the sheet S is pulled back in the −Y direction. At this time, the rear end E of the first surface of the sheet S becomes the front end E of the second surface, guided downward along the flapper 92 of the double-sided switching flapper 9, and enters the reversing path 11 through the branch port 109. The sheet S that has entered the reversing path 11 is eventually nipped by the fourth conveying roller pair 115 that rotates in the same counterclockwise direction as the third conveying roller 101, further proceeds in the reversing path 11, and again passes through the merging portion 33. It is conveyed to the sheet sensor 4.

  FIG. 8 shows a state in which the front end E of the second surface of the sheet S has passed through the sheet sensor 4 and reached the first conveying roller pair 5. In contrast to the state shown in FIG. 5, the front and back of the sheet S and the front and rear (front and rear ends) are reversed. Even if the second surface front end E of the sheet S reaches the first transport roller pair 5, the second surface front end E advances to the position of the print head 72 while the transport motor 205 rotates in the reverse direction. There is nothing.

  In step S107, the MPU 201 determines whether the detection result of the sheet sensor 4 is ON. If the detection result of the sheet sensor 4 is ON, the MPU 201 proceeds to step S108. On the other hand, if the detection result of the sheet sensor 4 is not ON, the MPU 201 determines that the reversal of the sheet S has failed and jumps to step S114 to stop the printing operation.

  In step S108, the MPU 201 stops the conveyance motor 205 and releases the nip of the third conveyance roller pair 110. Specifically, the nip adjustment motor 211 is driven via the nip adjustment motor driver 212 to rotate the pressure contact release cam 105. As a result, the pressure release cam 105 pushes up and rotates the spur holder 103 to separate the spur 102 from the third conveying roller 101.

  Thereafter, the MPU 201 proceeds to step S109 and executes a printing operation for the second surface. That is, the conveyance motor 205 is driven while checking the rotary encoder 53, and the sheet S is conveyed to a position where the head of the image is printed. Then, main scanning in which the carriage 71 is moved at a predetermined speed while ejecting ink from the print head 72 according to the print data and conveyance operation for conveying the sheet S in the Y direction by a distance corresponding to the print width of the print head 72 are alternately performed. Repeat.

  FIG. 9 is a diagram illustrating the sheet conveyance state immediately after starting the printing operation on the second surface in step S109. By repeating the main scanning and the conveying operation alternately as described above, the sheet S gradually advances in the Y direction from the state of FIG. At this time, the MPU 201 drives the conveyance motor 205 so as to rotate the first conveyance roller 52 and the second conveyance roller 81 in the forward direction (clockwise), so that the third conveyance roller 101 also moves in the forward direction (clockwise). Rotate. Further, as described above, since the reverse conveying roller 113 is not driven when the third conveying roller 101 rotates clockwise, the reverse conveying roller 113 stops when the printing operation on the second surface is started. It will be in the state.

  The MPU 201 counts the sheet conveyance amount from the position where the sheet sensor 4 detects the second surface leading edge E based on the output value of the rotary encoder 53 during the printing operation on the second surface. Then, assuming that the sheet S being conveyed is the maximum size sheet handled by the apparatus, it is determined whether or not the rear end T of the second surface has passed the position of the third conveying roller pair 110 and passed. If it is determined that the process has been performed, the process proceeds to step S110.

  In step S110, the MPU 201 causes the released nip of the third transport roller pair 110 to act again. Specifically, the nip adjustment motor 211 is driven via the nip adjustment motor driver 212, the pressure contact release cam 105 is rotated, the spur holder 103 that has been pushed up is lowered, and the spur 102 is brought into contact with the third transport roller 101. . FIG. 10 is a diagram illustrating a sheet conveyance state during the printing operation on the second surface after the nip of the third conveyance roller pair 110 is resumed in step S110.

  As described above, in this embodiment, the rear end T of the second surface has already passed the position of the third conveying roller pair 110 even when a sheet of any size that can be handled is conveyed. The nip of the third conveyance roller pair 110 is applied at a timing that can be regarded as the same. Thus, when the second surface tip E reaches the third transport roller pair 110 as the printing process proceeds, the third transport roller pair 110 is connected to the first transport roller pair 5 and the second transport roller. The sheet rotates in the same direction as the pair 8 and can be discharged without difficulty in the Y direction.

  When the second surface rear end T of the sheet S has not yet reached the sheet sensor 4 at the time when the printing operation on the second surface is completed, the MPU 201 selects the first sheet S according to the image size and the sheet size. The sheet S is conveyed by a distance that the rear end T of the second surface passes the sheet sensor 4.

  In step S <b> 111, the MPU 201 determines whether the second surface rear end T of the sheet S has passed the sheet sensor 4. If the rear end T of the second surface of the sheet S is not detected, it is determined that the conveyance is defective, and the process jumps to step S114. On the other hand, when the rear end T of the second surface of the sheet S is detected, the process proceeds to step S112.

  In step S112, the MPU 201 conveys the sheet S until the second surface rear end T of the sheet S passes through the third conveying roller pair 110 and is discharged from the apparatus. Specifically, the conveyance motor 205 is driven while checking the rotary encoder 53, and the sheet S is conveyed by a distance slightly longer than L2 from the position where the second surface rear end T of the sheet S is detected.

  In step S113, the MPU 201 determines whether a print command for the next sheet has been input. If it is input, the process returns to step S101, and a series of double-sided printing for the next sheet S is executed. If it has not been input, this process is terminated.

  In the printing apparatus 1 of the present embodiment described above, the distance L3 between the first conveyance roller pair 5 and the third conveyance roller pair 110 is designed to be sufficiently shorter than the longitudinal distance (127 mm) of the photo L size. . For this reason, at the timing when the printing operation is started on the second surface of a relatively large sheet such as A4 size, the middle of the sheet S is the fourth conveying roller pair 115, the rear end of the second surface as shown in FIG. T (first surface tip) is nipped by the third conveying roller pair 110. Therefore, if the third conveying roller pair 110 that rotates clockwise at this timing keeps the sheet nipped, the region of the sheet S that is nipped by the third conveying roller pair 110 is the third conveying roller 101. It will enter the branch port 109 against the conveying force. That is, the surface of the sheet S may be damaged. Further, a load is also applied to the conveyance by the first conveyance roller pair 5 and the second conveyance roller pair 8, and there is a possibility that the image printed between these two pairs of rollers may be disturbed due to a conveyance error. .

  However, as in this embodiment, if the nip of the third conveying roller pair 110 is released in step S108 before starting the printing operation on the second surface, the second surface rear end E (first surface) The vicinity of the tip) passes through the position of the third conveying roller pair 110 without receiving any resistance. Also, with respect to the fourth conveying roller pair 115 arranged in the middle of the reversing path 11, since the reversing conveying roller 113 is not driven, the sheet S only slides on the reversing conveying roller 113 and hardly receives resistance. . That is, according to the printing apparatus of the present embodiment, even when handling sheets of any size, normal printing processing can be performed on both sides of the sheet while stably conveying the sheet.

(Second Embodiment)
Also in this embodiment, basically, similarly to the first embodiment, the duplex printing is executed according to the flowchart shown in FIG. 4 using the printing apparatus shown in FIGS. The present embodiment is different from the first embodiment in the configuration of the discharge unit 10.

  FIGS. 11A and 11B are diagrams illustrating the configuration of the discharge unit 10 used in the present embodiment. In the first embodiment, the nip of the third conveyance roller pair 110 is switched between the action and the release, but in this embodiment, the mechanism can adjust the strength if the nip is acted.

  The spur holder frame 108 of this embodiment is T-shaped, and is connected to a spur holder 103 that holds the spur 102 at its lower end. In addition, the pressure lever 151 is rotatably supported via the pressure lever rotation shaft 152 at the left end (upstream side) of the T path type, and the pressure release cam rotation shaft is supported at the right end (downstream side) of the T path type. An elliptical pressure release cam 105 is rotatably supported via 106. The pressure lever 151 extends in the downstream direction to a position where it can contact the pressure release cam 105, and the rotation position of the pressure lever 151 is adjusted according to the rotation position of the pressure release cam 105. On the other hand, a spur pressure spring 107 is arranged between the pressure lever 151 and the spur holder 103 in the Z direction, and urges the spur 102 toward the third transport roller 101. With the above configuration, the strength of the nip force of the third transport roller pair 110 varies depending on the rotational position of the pressure release cam 105.

  FIG. 11A shows a state in which the nip force of the third transport roller pair 110 is set strongly. The rotational position of the pressure release cam 105 is fixed so that the major axis of the ellipse is parallel to the Z axis, and the tip of the pressure release cam 105 pushes down the pressure lever 151 to compress the spur pressure spring 107. As a result, the urging force of the spur pressure spring 107 against the spur 102 is increased, and the nip force of the third transport roller pair 110 is increased.

  FIG. 11B shows a state where the nip force of the third transport roller pair 110 is set weak. The rotational position of the pressure release cam 105 is fixed so that the short axis of the ellipse is parallel to the Z axis, and the pressure lever 151 is pushed up by the restoring force of the spur pressure spring 107. As a result, the urging force of the spur pressure spring 107 with respect to the spur 102 is weakened, and the nip force of the third transport roller pair 110 is weakened.

  Even when the discharge roller unit 10 configured as described above is used, the MPU 201 changes the nip force of the third conveying roller pair 110 in steps S108 and S110 in FIG. An effect equivalent to that of the embodiment can be obtained.

  On the other hand, unlike the first embodiment, the present embodiment does not completely release (release) the nip of the third conveyance roller pair 110 for the reversing operation of the sheet S, but the strength of the nip force. Is adjusted. For this reason, the sheet S opposes the conveying force of the third conveying roller 101 at the stage where the printing operation of the second surface is started with the third conveying roller pair 110 nipping the rear end T of the second surface. The situation that progresses also occurs. However, a certain amount of nip force may be necessary to adjust the posture of the sheet S and stabilize its conveyance. In this embodiment, the nip force is increased or decreased according to the rotational position of the pressure release cam 105. It can be adjusted continuously. That is, in the present embodiment, the nip force, that is, the rotational position of the pressure release cam 105 is adjusted according to the thickness of the sheet S, the ease of scratching the surface, the coefficient of friction with the roller, etc. It is possible to set a proper conveying force.

(Third embodiment)
Also in this embodiment, basically, similarly to the first embodiment, the duplex printing is executed according to the flowchart shown in FIG. 4 using the printing apparatus shown in FIGS. In this embodiment, the nip force of the third conveyance roller pair 110 is adjusted by providing a mechanism that is characteristic of the configuration in which the driving force is transmitted from the conveyance motor 205 to the third conveyance roller 101.

  FIGS. 12A and 12B are diagrams illustrating a gear train configuration that transmits driving force from the transport motor 205 to the third transport roller 101 in the present embodiment. The driving force of the conveyance motor 205 rotates the drive transmission gear 181 by a not-shown interlocking mechanism. A drive transmission shaft 182 and a sun gear 183 that rotate integrally with the drive transmission gear 181 are attached to the drive transmission gear 181. Further, a planetary gear holder 184 that can be rotated about the drive transmission shaft 182 is attached to the drive transmission shaft 182.

  At both ends of the planetary gear holder 184, a planetary gear A185 and a planetary gear B186 that are connected to the sun gear 183 are arranged. That is, when the transport motor 205 is driven and the drive transmission gear 181 rotates, the sun gear 183 rotates through the drive transmission shaft 182, and the planetary gear A 185 and the planetary gear B 186 connected to the sun gear 183 also rotate simultaneously. . On the other hand, a third transport roller drive gear 187 connected to the third transport roller 101 is disposed at a position adjacent to the planetary gear holder 184 and connectable to the planetary gear A185 and the planetary gear B186. And the 3rd conveyance roller drive gear 187 can be connected with the planetary gear A185 and the planetary gear B186 according to the rotational position of the planetary gear holder 184, and can be cancelled | released.

  As shown in FIG. 12 (a), the planetary gear A185 is fixed to the planetary gear holder 184 so as to be rotatable with respect to a fixed portion 184a in which the rotation shaft and the claw are integrated. Further, as shown in FIG. 12 (b), a pressing spring 189 that acts in a direction to contact the planetary gear holder 184 is arranged inside the planetary gear A 185. Under such a configuration, when the sun gear 183 rotates, the planetary gear holder 184 generates a force that rotates in the same direction as the planetary gear A185 about the drive transmission shaft 182 via the planetary gear A185. On the other hand, the rotational position of the planetary gear holder 184 can also be adjusted by the control arm 188 engaging and moving with the boss 184b formed at the end of the planetary gear holder 184.

  As described above, the rotation position of the planetary gear holder 184 is changed by the rotation direction of the drive transmission gear 181 and the control arm 188. The driving force of the drive transmission gear 181 is transmitted to the third transport roller 101 via one of the planetary gear A185 and the planetary gear B186 according to the rotational position of the planetary gear holder 184. .

  FIGS. 13A and 13B are diagrams illustrating a configuration for switching between forward rotation and reverse rotation of the third conveyance roller 101. 13A and 13B, the clockwise direction coincides with the clockwise direction of FIGS. 1 and 5 to 10.

  As shown in FIG. 13A, when the drive transmission gear 181 rotates counterclockwise in the figure, the sun gear 183 also rotates counterclockwise, and the planetary gear A185 and the planetary gear B186 connected to the sun gear 183 are Rotate clockwise. As a result, the planetary gear holder 184 rotates counterclockwise about the drive transmission shaft 182, the planetary gear B 186 is connected to the third transport roller drive gear 187, and stops at that position. As a result, the third transport roller drive gear 187 rotates counterclockwise, and the third transport roller 101 connected thereto rotates clockwise. In this state, the sheet S nipped by the third conveyance roller pair 110 is conveyed in the conveyance direction (Y direction) in FIG.

  On the other hand, as shown in FIG. 13B, when the drive transmission gear 181 rotates clockwise in the figure, the sun gear 183 also rotates clockwise, and the planetary gear A185 and the planetary gear B186 connected to the sun gear 183 are Rotates counterclockwise. As a result, the planetary gear holder 184 rotates clockwise about the drive transmission shaft 182, and the planetary gear A 185 is connected to the third transport roller drive gear 187 and stops at that position. As a result, the third transport roller driving gear 187 rotates clockwise, and the third transport roller 101 connected thereto rotates counterclockwise. In this state, the sheet S nipped by the third conveyance roller pair 110 is conveyed in the reverse direction (-Y direction) in FIG.

  That is, when the first surface printing operation is performed in step S103 and the second surface printing operation is performed in step S109, the third conveying roller 101 is driven in the connected state described in FIG. S is conveyed in the Y direction. Further, when the sheet S is pulled back to the reverse path 11 in step S106, the third conveying roller 101 is driven in the connected state described in FIG. 13B, and the sheet S is conveyed in the -Y direction.

  FIGS. 14A and 14B are diagrams showing a mechanism for releasing the nip force of the third conveying roller pair 110 under the above-described configuration. FIG. 14A shows a state in which the control arm 188 is pulled in the −q direction from the state shown in FIG. When the control arm 188 moves in the -q direction, the boss 184b engaged with the control arm 188 also moves in the -q direction, and the planetary gear holder 184 rotates counterclockwise by a predetermined amount against the pressing spring 189. As a result, neither the planetary gear A185 nor the planetary gear B186 is connected to the third transport roller drive gear 187, and the driving force of the drive transmission gear 181 is not transmitted to the third transport roller 101.

  In this embodiment, the MPU 201 moves the control arm 188 in the −q direction in step S <b> 108 of FIG. 4 so that the driving force of the transport motor 205 is not transmitted to the third transport roller 101. In step S109, the transport motor 205 is rotated in the forward direction with the control arm 188 moved in the -q direction, and printing on the second surface is started. At this time, the connection state to the third transport roller 101 is the state shown in FIG.

  When printing on the second surface proceeds and the rear end T of the second surface passes the third transport roller pair 110, the MPU 201 moves the control arm 188 in the + q direction in step S110. Thereby, the boss 184 b is released from the pressure by the controller arm 188, and the planetary gear holder 184 is rotated by the urging force of the pressing spring 189. Since the drive transmission gear 181 rotates counterclockwise at this timing, the planetary gear holder 184 also rotates counterclockwise, the planetary gear B186 is connected to the third transport roller drive gear 187, and the third transport roller 101 Rotate clockwise (forward). That is, the connection state to the third transport roller 101 is the state shown in FIG.

  As described above, also in this embodiment, the nip force by the third conveying roller pair 110 can be reduced before starting the printing operation on the second surface. For this reason, the second surface rear end T (first surface front end) of the sheet S can pass through the position of the third conveying roller pair 110 in the direction of the reverse path 11 without receiving a large resistance. In particular, in this embodiment, since the discharge unit 10 as in the first embodiment and the second embodiment is not required, it is possible to achieve downsizing of the apparatus while obtaining the same effect as the above embodiment. It becomes possible.

  In the embodiment described above, the timing for resuming the nip of the third conveyance roller pair 110 in step S110 is determined based on the conveyance distance corresponding to the maximum sheet size handled by the apparatus. It is not limited to such a form. For example, a mechanical timer may be prepared separately from the rotary encoder 53, and the nip may be resumed after a predetermined time has elapsed after the sheet sensor 4 detects the trailing edge of the sheet S.

  In the embodiment described above, the printing apparatus has been described as an example. However, the process performed on both sides of the sheet in the printing apparatus of the present invention is not limited to the printing process. The process applied to both sides of the sheet may be a process of reading images already printed on both sides of the sheet, or may be a process of overcoating the sheet surface. In any case, any apparatus that performs various sheet processing (processing, coating, irradiation, inspection, etc.) on both sides of the supplied sheet may be used.

1 Printing device (printing device)
5 First conveying roller pair
7 Print unit
8 Second conveying roller pair
10 Discharge unit
11 Reverse path 110 Third conveyance roller pair 205 Conveyance motor
S sheet

Claims (7)

A print head for printing on the conveyed sheet;
A first pair of conveyance rollers disposed upstream of the print head in the conveyance direction and conveying a sheet while nipping the sheet;
A second conveyance roller pair disposed downstream of the print head in the conveyance direction and conveying the sheet while nipping the sheet;
A third conveying roller pair that is disposed further downstream than the second conveying roller pair in the conveying direction and conveys the sheet while nipping the sheet;
A first conveyance path for guiding the sheet in the order of the first conveyance roller pair, the second conveyance roller pair, and the third conveyance roller pair;
A second conveyance path for guiding a sheet from the third conveyance roller pair to the first conveyance roller pair without passing through the second conveyance roller pair;
The first transport roller pair, the second transport roller pair, and the third transport roller pair are rotated in common in either the transport direction or the direction opposite to the transport direction. A driving source;
A printing apparatus comprising:
When a sheet near the third conveyance roller pair is nipped by the first conveyance roller pair via the first conveyance path, and when a sheet near the third conveyance roller pair is The printing apparatus according to claim 1, wherein the third conveying roller pair has a different conveying force when nipped by the first conveying roller pair via the second conveying path. When a sheet in the vicinity of the third conveyance roller pair is nipped by the first conveyance roller pair via the first conveyance path, the sheet is applied to the third conveyance roller pair with a predetermined pressure. Nip with
When a sheet in the vicinity of the third conveyance roller pair is nipped by the first conveyance roller pair via the second conveyance path, the nip of the third conveyance roller pair is released. The printing apparatus according to claim 1, wherein: When a sheet in the vicinity of the third conveyance roller pair is nipped by the first conveyance roller pair via the first conveyance path, the sheet is applied to the third conveyance roller pair with a predetermined pressure. Nip with
When a sheet in the vicinity of the third conveying roller pair is nipped by the first conveying roller pair via the second conveying path, the sheet is placed on the third conveying roller pair by the predetermined amount. The printing apparatus according to claim 1, wherein the nip is performed at a pressure lower than the pressure. When a sheet in the vicinity of the third conveyance roller pair is nipped by the first conveyance roller pair via the first conveyance path, the sheet is applied to the third conveyance roller pair with a predetermined pressure. Nip with
When a sheet in the vicinity of the third conveying roller pair is nipped by the first conveying roller pair via the second conveying path, the driving force of the driving source is applied to the third conveying roller pair. The printing apparatus according to claim 1, wherein the printing apparatus is not transmitted. The first transport path is a path for printing on the sheet;
5. The printing apparatus according to claim 1, wherein the second conveyance path is a path for reversing the front and back of the sheet.   The printing apparatus according to claim 1, wherein the print head is an inkjet head and is mounted on a carriage that reciprocates. A first process for performing a predetermined process on the first surface of the sheet while conveying the sheet by the first conveying roller pair and the second conveying roller pair disposed downstream of the first conveying roller pair. Process,
A first conveying step of conveying the sheet on which the first processing step has been performed by a third conveying roller pair disposed further downstream than the second conveying roller pair;
By rotating the third conveying roller pair in a direction opposite to the first conveying step, the sheet on which the first conveying step has been performed is transferred to the first conveying roller without passing through the second conveying roller pair. A reversing step for guiding to one transport roller pair;
A second processing step of performing the predetermined processing on the second surface of the sheet while transporting the sheet on which the reversing step has been performed by the first transport roller pair and the second transport roller pair. A sheet conveying method comprising:
In the second processing step, when the trailing edge of the sheet is in the vicinity of the third conveying roller pair and when the leading edge of the sheet is in the third conveying roller pair, the third conveying roller A sheet processing method characterized in that the conveying force of the pair is different.

Images