JP2004026373A - Two-side printing device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a one-process, both sides printing device capable of performing single side printing without using a wasteful master unit, producing a printed matter of good picture quality when both sides printing is to be made, and suppressing occurrence of a jam in transporting sheets of paper. <P>SOLUTION: The both sides printing device comprises a printing part 22, a sheet feed part 4, a sheet discharge part 6, a refeeding means 9 having an auxiliary tray 8, and a changeover member 10, wherein the refeeding means 9 has a refeeding transport unit 25 to transport each surface-printed sheet PA on the auxiliary tray 8 toward a press roller 13 and a sheet receptacle plate 40 installed over the oversurface of the transport unit 25 with a certain gap reserved in between and receiving one end of the surface-printed sheet PA guided to the auxiliary tray 8 by the changeover member 10, and the sheet receptacle plate 40 is arranged capable of reciprocating in the same direction as the transportation of the surface-printed sheet PA by the refeeding transport unit 25. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a double-sided printing apparatus capable of performing printing on both sides of a sheet in one process, and more particularly, to a sheet re-feeding apparatus that re-feeds a sheet having a front side printed on a front side toward a printing unit. It relates to the structure of the means.
[0002]
[Prior art]
Conventionally, digital thermosensitive stencil printing has been known as a simple printing method. In stencil printing, a thermal head in which fine heating elements are arranged in a line is brought into contact with a heat-sensitive stencil master (hereinafter referred to as "master"), and the master is conveyed while energizing the heating elements in a pulsed manner. In accordance with the above, the master is heated and melt-punched, and after the master is wound around the outer peripheral surface of the porous cylindrical plate cylinder, the outer peripheral surface of the plate cylinder is pressed by pressing means such as a press roller via a sheet, The printed image is obtained by transmitting ink from the master perforated portion and transferring the ink to paper.
[0003]
In recent years, in stencil printing, double-sided printing, in which printing is performed on both sides of a sheet, has been frequently performed in order to reduce the amount of paper consumption and the storage space for documents. In the conventional double-sided printing, the paper loaded in the paper feeding unit is passed through the printing unit according to the conventional method, and after printing on one side, the sheet is turned over, and then passed through the printing unit again to print on the other side. Although a two-sided printed material has been obtained, there is a problem in that it is troublesome to set the paper once discharged in the paper feeding unit again or to align the paper after one-sided printing.
[0004]
In addition, since the ink on the printed material after printing is not sufficiently dried, if printing is immediately performed on the back side, the conveyance roller or press roller is pressed against the image area, and the printed image becomes dirty or disturbed. This has occurred, and in most cases, printing on the back surface has been performed after several hours. In particular, when there is a solid image portion, drying for a long time is necessary, and printing on the back surface has been performed the next day.
Thus, in duplex printing, after printing on one side, the paper must be dried for a long time before printing on the other side, and since the paper passes through the printing unit twice, it can be printed even in the net printing time. This requires twice as much time as that of the conventional method, and has a problem that it takes too much time.
[0005]
In order to solve the above-mentioned problems, a first plate cylinder, a second plate cylinder disposed to face the first plate cylinder via a sheet transport path, and an outer peripheral surface of the first plate cylinder and a second plate cylinder are provided. A stencil printing apparatus for obtaining a double-sided printed matter in one step by operating the contacting / separating means to press the plate cylinders together with each other, comprising: 6-71996 and JP-A-6-135111.
[0006]
A first plate cylinder, a first pressing means disposed to face the first plate cylinder via the sheet transport path and provided so as to be able to press and separate from the first plate cylinder; A second plate cylinder disposed downstream of the plate cylinder in the sheet conveyance direction and opposite to the first plate cylinder via the sheet conveyance path, and opposed to the second plate cylinder via the sheet conveyance path; A second pressing means disposed so as to be able to be pressed against and separated from the second plate cylinder, and after the first plate cylinder and the first pressing means are pressed against each other, the second plate JP-A-8-90893 and JP-A-8-142577 disclose a stencil printing apparatus which obtains a double-sided printed matter in one step by pressing a cylinder and a second pressing means.
[0007]
Further, a divided plate-making master in which two first plate-making images and second plate-making images are arranged in the rotation direction of the plate cylinder is used, and a press roller is directly attached to the plate cylinder in correspondence with the image area of one of the plate-making images. A first step of transferring a first print image corresponding to one of the plate making images to the outer peripheral surface of the press roller by rotating together with the plate cylinder while making contact with the plate cylinder, and after the first step, an image area of the other plate making image and the first printing At the same time, the first print image is re-transferred to the first surface corresponding to the press roller of the sheet while rotating the press roller with the plate cylinder via the sheet so as to correspond to the image, A stencil printing method for obtaining a double-sided printed matter in one step by a second step of transferring a second printing image corresponding to the other plate making image to a second surface corresponding to the plate cylinder of the paper, and a stencil printing apparatus performing the same. Disclosed in JP-A-8-332768 It has been.
[0008]
[Problems to be solved by the invention]
However, in the technology disclosed in JP-A-6-71996 and JP-A-6-135111, two plate cylinders are arranged up and down and they are pressed against each other. It is necessary to press the plate cylinders against each other, and one of the plate cylinders must be wound with a pre-made master, and the other plate cylinder must be wound with an unprinted master. There is a problem that it is done. Further, in order to press two plate cylinders each having a clamper for holding a master on the outer peripheral surface thereof, it is necessary to separate the plate cylinders at positions where the respective clampers face each other. This reduces the area in which the plate cylinders are in contact with each other and reduces the image amount area.Therefore, it is necessary to increase the outer diameter of each plate cylinder in order to secure the image amount area. In addition, there is a problem that loud noise is generated when the plate cylinders come into contact with each other.
[0009]
In the techniques disclosed in JP-A-8-90893 and JP-A-8-142577, it is necessary to wind an unprinted master on one of the plate cylinders during single-sided printing, as described above. Is consumed. Also, since two plate cylinders are arranged in series in the paper transport direction, the size of the apparatus is almost twice as large as that of a stencil printing apparatus for single-sided printing, and it is difficult to secure the installation space. There is.
[0010]
According to the technique disclosed in Japanese Patent Application Laid-Open No. 8-332768, one of a first plate-making image and a second plate-making image (a front image and a back image) is directly transferred from a plate cylinder to a sheet, and the other is a press roller. Since the image is transferred to the sheet and then re-transferred to the sheet, there is a problem that the image density on the sheet differs between the front side and the back side.
[0011]
The present invention solves the above-described problems, can perform single-sided printing without using a wasteful master, can obtain a printed matter with good image quality during double-sided printing, and can suppress an increase in installation space. It is an object of the present invention to provide a one-step double-sided printing apparatus.
[0012]
[Means for Solving the Problems]
According to the first aspect of the invention, there is provided a plate cylinder for winding a divided plate-making master having two first plate-making images and two second plate-making images arranged in the longitudinal direction on an outer peripheral surface, and a contact with the plate cylinder. A printing unit having a press roller provided detachably, a paper feeding unit for feeding paper toward the printing unit, and a paper discharging unit for discharging printed paper printed on the printing unit to the outside of the machine And an auxiliary tray for temporarily storing the surface-printed paper having a print image formed on its surface in the printing unit, and re-printing the front-printed paper stored on the auxiliary tray toward the printing unit. A re-feeding means for feeding paper, and a switching member for guiding the paper passing through the printing unit to either the auxiliary tray or the paper discharging unit, and the first sheet from the paper feeding unit during duplex printing. Paper is fed to the printing unit, and the first plate-making image or After printing any one of the second plate-making images and guiding the printed first sheet to the auxiliary tray by the switching member, the second sheet is fed from the sheet feeding section to the printing section. Then, either the first plate-making image or the second plate-making image is printed on the front surface, and the first sheet is re-fed to the printing unit by the re-feeding means, and the first plate-making image is printed on the back surface. Or a two-sided printing apparatus which prints one of the second plate-making images and guides the first sheet by the switching member to the discharge section and the second sheet by the auxiliary tray, respectively. The sheet re-feeding unit has a sheet conveying member having an upper surface exposed on the upper surface of the auxiliary tray that conveys the front-printed sheet stored on the auxiliary tray toward the press roller. Lower than the upper surface of the paper transport member. And a sheet receiving plate that is provided above through the gap and receives one end of the front side printed sheet guided toward the auxiliary tray by the switching member, and the sheet receiving plate is located above the auxiliary tray. The front-printed sheet can be reciprocated in the same direction as the direction in which the front-printed sheet is transported by the refeeding transport unit.
[0013]
According to a second aspect of the present invention, in the double-sided printing apparatus according to the first aspect, the sheet receiving plate is closest to the press roller during one rotation of the plate cylinder, and receives one end of the surface-printed sheet. And the other end of the surface-printed sheet farthest from the press roller on the upper surface makes a second reciprocation between the second position where the other end of the sheet comes into contact with the sheet conveying member, and the surface guided by the switching member The printed sheet occupies the first position when one end of the printed sheet falls onto the auxiliary tray.
[0014]
According to a third aspect of the present invention, in the double-sided printing apparatus according to the second aspect, the re-feeding unit further moves the front-printed sheet transported by the re-feed transport unit at a predetermined position before the press roller. A re-feeding positioning member for temporarily stopping, and when the paper receiving plate occupies the second position, the other end of the front side printed paper abuts on the re-feeding positioning member to re-feed the paper. The surface-printed sheet is temporarily stopped by a positioning member, and one end of the surface-printed sheet falls from the sheet receiving plate.
[0015]
According to a fourth aspect of the present invention, in the double-sided printing apparatus according to the third aspect, a front-side printed sheet detecting member for detecting that the other end of the front-side printed sheet is close to the re-feeding positioning member is further provided. After the other end is detected by the front-side printed sheet detecting member, the sheet receiving plate is moved from the second position to the first position.
[0016]
According to a fifth aspect of the present invention, in the double-sided printing apparatus according to any one of the first to fourth aspects, the auxiliary tray is guided by the switching member and falls on the sheet receiving plate. An end fence with which one end of the front side printed paper is in contact is provided, and the paper receiving plate has a fitting portion that fits into the end fence when occupying a second position.
[0017]
According to a sixth aspect of the present invention, in the double-sided printing apparatus according to any one of the first to fourth aspects, the sheet receiving plate is guided by the switching member and falls on the upper surface thereof. And an end fence with which one end of the used paper is in contact.
[0018]
According to a seventh aspect of the present invention, in the double-sided printing apparatus according to any one of the first to sixth aspects, the sheet receiving plate further includes a pair of side edges for aligning both side edges of the front side printed sheet. Characterized by having side fences.
[0019]
According to an eighth aspect of the present invention, in the double-sided printing apparatus according to any one of the first to seventh aspects, the reciprocating path of the sheet receiving plate is the auxiliary tray for the front-printed sheet. It is characterized in that it is provided as inclined as possible so as to be almost the same as the path of the fall.
[0020]
【Example】
FIG. 1 shows a double-sided printing apparatus to which an embodiment of the present invention can be applied. In FIG. 1, a duplex printing apparatus 1 includes a printing unit 2, a plate making unit 3, a sheet feeding unit 4, a plate discharging unit 5, a sheet discharging unit 6, an image reading unit 7, an auxiliary tray 8, a sheet re-feeding unit 9, a switching member 10, and the like. have.
[0021]
The printing unit 2 disposed substantially at the center of the apparatus main body 11 has a plate cylinder 12 and a press roller 13.
The plate cylinder 12 has a pair of end plates (not shown) rotatably supported by a spindle 14 also serving as an ink supply pipe, a porous support plate (not shown) wound around the outer peripheral surface of each end plate, and a not-shown plate. It mainly comprises a mesh screen (not shown) wound around the outer peripheral surface of the porous support plate. The mesh screen is rotatably driven by the plate cylinder driving means 121 (see FIG. 9) and is detachably attached to the apparatus main body 11. It is configured. In the present embodiment, the plate cylinder 12 has a size capable of obtaining a printed matter of A3 size at the maximum during single-sided printing.
[0022]
Inside the plate cylinder 12, an ink supply means 15 is provided. The ink supply means 15 has a support shaft 14, an ink roller 16, a doctor roller 17, and the like.
The ink roller 16 is rotatably supported between side plates (not shown) provided in the plate cylinder 12, and its peripheral surface is arranged close to the inner peripheral surface of the plate cylinder 12. It is driven to rotate in the same direction as the body 12. The doctor roller 17 is also rotatably supported between the side plates, and its peripheral surface is arranged close to the peripheral surface of the ink roller 16, and is driven to rotate in the opposite direction to the plate cylinder 12 by driving means (not shown). . The support shaft 14 is provided with a plurality of small holes. The ink supplied from the support shaft 14 is accumulated in a space formed in the vicinity of the ink roller 16 and the doctor roller 17 and having a wedge-shaped cross section. A reservoir 18 is formed.
[0023]
On the outer peripheral surface of the plate cylinder 12, there is formed a stage portion 19a which forms a plane along one generatrix of the plate cylinder 12. On this stage portion, a clamper for holding the leading end of the master on the outer peripheral surface of the plate cylinder 12 is formed. 19b is provided. The clamper 19b is opened and closed by opening and closing means (not shown) when the plate cylinder 12 is rotated to a predetermined position.
[0024]
A press roller 13 is provided below the plate cylinder 12. The press roller 13 is formed by winding an elastic body such as rubber around a metal core 13 a, and is provided extending in the axial direction of the plate cylinder 12. As shown in FIG. 2, both ends of the core 13 a of the press roller 13 are rotatably supported by a pair of arm members 20. Each of the arm members 20 having a substantially L-shape is integrated by a swing shaft 21 attached to a portion near the bent portion, and the swing shaft 21 is rotatably supported by the apparatus main body 11. I have. In this embodiment, at least the peripheral surface of the press roller 13 is formed of a member having ink repellency such as polytetrafluoroethylene resin.
[0025]
Between each arm member 20, in addition to the press roller 13, a re-feed guide member 22, a re-feed registration roller 23, a re-feed positioning member 24, a re-feed transport unit 25, a cleaning roller 26, a guide plate 27, etc. Is provided.
[0026]
The re-feed guide member 22 disposed near the right side of the press roller 13 is integrally provided on each of the support shafts 28a, 29a, and 30a, and presses the respective peripheral surfaces against the peripheral surface of the press roller 13. Roller rollers 28, 29, and 30, and a paper guide plate 31 formed into a curved surface for causing the surface-printed paper PA to follow the peripheral surface of the press roller 13. Both ends of each support shaft 28a, 29a, 30a are rotatably supported by each arm member 20, and are urged toward the core 13a by urging means (not shown). The rollers 28, 29, 30 are integrally attached to the corresponding support shafts 28a, 29a, 30a at predetermined intervals over substantially the entire width of the press roller 13.
[0027]
The paper guide plate 31 is disposed at a position separated from the peripheral surface of the press roller 13 by a predetermined distance that is smaller than the radius of each of the rollers 28, 29, and 30. Both ends are fixed to each arm member 20. Have been. The paper guide plate 31 is formed so as to have a curved surface centered on the core portion 13 a, and the paper guide plate 31 is used for bringing the peripheral surfaces of the rollers 28, 29, 30 into contact with the peripheral surface of the press roller 13. (Not shown) are formed.
[0028]
Below the press roller 13, a re-feed registration roller 23 is provided. The roller-shaped re-feed registration roller 23 is rotatably supported by a support shaft 23 a, and the support shaft 23 a is attached to one end of a swing arm 32. The swing arm 32, which has a substantially U-shape, is supported by a support shaft 32a fixed between the arm members 20 so that the bent portion is swingable. The pressing roller 13 is determined to be located substantially at the center in the width direction, and to be located at an intermediate position between the rollers 30 in which the pressing roller 13 is disposed.
[0029]
At the other end of the swing arm 32, a plunger 33 a of a solenoid 33 attached to one arm member 20 via a bracket (not shown), and one end is fixed to the one arm member 20 and supported by the swing arm 32. The other end of a tension spring 34 for applying a biasing force in the counterclockwise direction in FIG. 2 around the shaft 32a is attached. With this configuration, when the solenoid 33 is actuated, the re-feed registration roller 23 occupies a pressing position indicated by a solid line in FIG. 2 in which the circumferential surface thereof is pressed against the circumferential surface of the press roller 13 with a predetermined pressing force. When the operation is released, the peripheral surface is separated from the peripheral surface of the press roller 13 by the urging force of the tension spring 34, and occupies a separation position indicated by a two-dot chain line in FIG.
[0030]
At the lower left of the press roller 13, a paper re-feeding / conveying unit 25 is provided. The re-feeding conveyance unit 25 has a conveyance unit main body 35, a driving roller 36, a driven roller 37, an endless belt 38 as a sheet conveyance member, a suction fan 39, and the like. Have.
[0031]
The transport unit main body 35, which is a housing whose upper surface is open and whose width is slightly smaller than the interval between the arm members 20, is not shown on both sides on the upstream side and the downstream side in the paper transport direction. Each bearing (not shown) rotatably supports the drive shaft 36a and the driven shaft 37a. Both ends of the drive shaft 36a penetrate both side surfaces of the transport member main body 35, and the penetrated both ends are rotatably supported by bearing members (not shown) provided on the apparatus main body 11. A drive gear (not shown) is attached to one end of the drive shaft 36a, and the drive shaft 36a is rotated by a transport unit drive motor 122 (see FIG. 9) provided on the apparatus main body 11. The driven shaft 37 a is configured such that both ends do not penetrate both side surfaces of the transport unit main body 35.
[0032]
Bosses 35a are integrally provided on both outer sides of the upstream end of the transport unit body 35 in the paper transport direction, and the bosses 35a are respectively fitted into elongated holes (not shown) formed in the arm members 20. Have been. With this configuration, when the press roller 13 is brought into contact with or separated from the plate cylinder 12 by the press roller contacting / separating mechanism 55 described later, the transport unit main body 35 is centered on the drive shaft 36 a with the swing of each arm member 20. Swinging is possible.
[0033]
The plurality of roller-shaped driving rollers 36 are integrally attached to the driving shaft 36a, and a predetermined interval is provided between the driving rollers 36. The plurality of driven rollers 37 having the same shape as the driving roller 36 are integrally attached to the driven shaft 37 a at the same intervals as the driving rollers 36. An endless belt 38 is stretched between each drive roller 36 and each corresponding driven roller 37 with a predetermined tension. The endless belt 38 made of a frictional resistance member is moved in a direction indicated by an arrow in FIG. 2 by driving the drive shaft 36 a by the transport unit drive motor 122.
[0034]
The suction fan 39 is integrally attached to the lower surface of the transport unit main body 35, and the auxiliary tray 8 is integrally attached to the upper surface of the transport unit main body 35. As shown in FIG. 3, the auxiliary tray 8 is configured such that a part of the peripheral surface of each of the rollers 36 and 37 faces the paper transport surface. A plurality of openings 8b are formed, and two end fences 8a for receiving one end of the front-printed paper PA sent from the printing unit 2 are integrally provided at the downstream end in the paper transport direction. Has been.
[0035]
At the upstream end of the auxiliary tray 8 in the sheet conveyance direction, a re-feed for temporarily stopping the other end of the front side printed paper PA to be re-supplied to the printing unit 2 by the re-feed conveyance unit 25 at a fixed position. A paper positioning member 24 is provided. In this embodiment, two re-feed positioning members 24 are provided, each of which is integrally attached to the auxiliary tray 8. Further, the auxiliary tray 8 is provided with a sensor 8c as a front-side printed sheet detecting member for detecting that the other end of the front-side printed sheet PA is close to the re-feeding positioning member 24. The sensor 8c outputs a signal to a control unit 129 described later when detecting the other end of the front-side printed paper PA.
[0036]
A hole (not shown) is provided on the lower surface of the transport unit main body 35, which is a mounting surface of the suction fan 39, so that the suction fan 39 operates to apply a negative pressure to the inside of the transport unit main body 35, which is a housing. The surface printed paper PA is sucked on the upper surface of each endless belt 38 that is generated and moves. The suction force of the suction fan 39 and the frictional resistance force of the endless belt 38 indicate that when the other end of the surface-printed paper PA comes into contact with the re-feeding positioning member 24, the surface-printed paper PA and each endless belt 38 The strength is set to such a degree that slippage occurs between them.
[0037]
The above-mentioned auxiliary tray 8, re-feed guide member 22, re-feed registration roller 23, re-feed positioning member 24, and re-feed transport unit 25 constitute a re-feed means 9. The sheet re-feeding means 9 has the sheet receiving plate 40 shown in FIGS. 1 and 3, and the sheet receiving plate 40 will be described later.
[0038]
A cleaning roller 26 that cleans the peripheral surface of the press roller 13 is disposed near the press roller 13 and above the sheet re-feeding and conveying unit 25. The cleaning roller 26 having a width substantially equal to the width of the press roller 13 has at least a surface made of a highly hygroscopic material such as Japanese paper or sponge, and integrally has a core 26a at the center thereof. . The cleaning roller 26 is rotatably supported by fitting a core portion 26a into an elongate hole (not shown) formed in each of the arm members 20, and is pressed by an urging means (not shown) provided in the elongate hole. 13 and is constantly pressed against the peripheral surface of the press roller 13 with a predetermined pressing force. The cleaning roller 26 is rotated by the cleaning roller driving means (not shown) provided on one arm member 20 in the same direction as the press roller 13 during rotation of the press roller 13 so that the peripheral speed of the press roller 13 is about 1/10. It is driven to rotate at the peripheral speed.
[0039]
A guide plate 27 is provided at the upper left of the cleaning roller 26. The guide plate 27, which is a plate material, has both ends fixed to the arm members 20 so that the front-printed paper PA sent from the printing unit 2 does not touch the cleaning roller 26 and heads toward the auxiliary tray 8. To guide. The guide plate 27 is provided at a position close to each peripheral surface of the press roller 13 and the cleaning roller 26.
[0040]
A rotatable cam follower 41 is arranged on the other end of each arm member 20 opposite to the one end on which the press roller 13 is supported, so as to face each other. In the vicinity of the position where the cam follower 41 of each arm member 20 is provided, the other end of a printing pressure spring 42 having one end fixed to the apparatus main body 11 is attached. Thereby, each arm member 20 is provided with a biasing force in the clockwise direction about the swing shaft 21 in the figure.
[0041]
Near the left side of each cam follower 41, a multi-stage cam 43 having three cam plates 43A, 43B, 43C is provided, respectively. Each of the cam plates 43A, 43B, 43C is fixed at a predetermined gap to a cam shaft 44 supported at both ends by the apparatus main body 11 so as to be rotatable and movable in the direction of the paper of FIG. The plate 43B, the cam plate 43A, and the cam plate 43C are arranged in this order. Each of the cam plates 43A, 43B, and 43C has a base that is a disc that is concentric with the cam shaft 44, and a protrusion that has the same amount of protrusion. As shown in FIG. 4, the multi-stage cam 43 is driven by a plate gear driving means via a drive gear 45 attached to a cam shaft 44 and a transmission gear 47 attached to a support shaft 46 rotatably supported by the apparatus main body 11. Rotational force is transmitted from the motor 121 and is rotated clockwise in FIG.
[0042]
The press roller 13 occupies the separated position shown in FIG. 2 in which the peripheral surface is separated from the peripheral surface of the plate cylinder 12 when any of the convex portions of each of the cam plates 43A, 43B, 43C comes into contact with the cam follower 41, When the contact between any of the protrusions and the cam follower 41 is released, the circumferential surface of the cam follower 41 occupies the pressed position shown in FIG. Each of the cam plates 43A, 43B, and 43C is configured such that when the press roller 13 occupies the pressed position, the base thereof does not contact the cam follower 41. The shape of the convex portion of each of the cam plates 43A, 43B and 43C is such that the contact range between the press roller 13 and the plate cylinder 12 is a range where the front surface region, the intermediate region and the rear surface region shown in FIG. The cam plate 43B is formed so as to be in the same range as the front surface region, and the cam plate 43C is formed so as to be in the range including the downstream portion, the intermediate region, and the back surface region of the front surface region. Further, the interval between the cam plates 43A, 43B, 43C is set to be sufficiently larger than the plate thickness of the arm member 20.
[0043]
In FIG. 2, near the right side of each arm member 20, there is provided a not-shown press roller locking means for inhibiting the swing of each arm member 20 in a state where the press roller 13 occupies the separated position. The press roller locking means (not shown) has a solenoid (not shown), and the state of holding each arm member 20 and the state of releasing the holding are selectively switched by turning on / off the solenoid (not shown). The solenoid (not shown) is operated in a state where the cam follower 41 is in contact with any one of the protrusions of the cam plates 43A, 43B, 43C.
[0044]
A moving arm 48 and a step cam 49 are provided near the lower portion of the cam shaft 44 as shown in FIG. The bent portion of the movable arm 48 having a substantially L-shape is attached to a support shaft 48 a rotatably supported by the apparatus main body 11. A roller 48 b is provided at one end of the movable arm 48, and a roller 48 b is provided at the other end. Each of the cam followers 48c is rotatably mounted. Further, the other end of the tension spring 50 having one end attached to the apparatus main body 11 is attached to a portion between the other end of the moving arm 48 and the bent portion. In the drawings, a clockwise urging force is applied.
[0045]
The roller 48b is arranged between the discs 44a and 44b fixed at an interval in the middle of the camshaft 44. The cam follower 48c moves its peripheral surface to the peripheral surface of the step cam 49 by the urging force of the tension spring 50. Abutted. The interval between the disks 44a, 44b is set to be slightly larger than the diameter of the roller 48b.
[0046]
The step cam 49 has three cam portions 49a, 49b, and 49c on its peripheral surface, and is fixed to a support shaft 51 rotatably supported by the apparatus main body 11. A gear 54 meshing with a gear 53 attached to an output shaft of a stepping motor 52 attached to the apparatus main body 11 is attached to the support shaft 51. It is driven to rotate in the direction. With this configuration, when the stepping motor 52 operates and the step cam 49 rotates, the moving arm 48 swings about the support shaft 48a, and the roller 48b pushes the disk 44a or the disk 44b, so that the cam shaft 44 is moved. 4 to the left and right.
[0047]
In each of the cam portions 49a, 49b, 49c, the cam follower 48c and the cam portion 49b contact each other so that the cam plate 43B can be brought into contact with the cam follower 41 when the cam follower 48c contacts the cam portion 49a. When the cam follower 48c and the cam portion 49c come into contact with each other, the cam shaft 44 is moved so that the cam plate 43C comes into contact with the cam follower 41 so that the cam plate 43A comes into contact with the cam follower 41. Each is formed in a shape to be moved.
[0048]
The above-described cam follower 41, printing pressure spring 42, multi-stage cam 43, press roller engaging means (not shown), moving arm 48, and step cam 49 constitute a press roller contact / separation mechanism 55. By operation, the press roller 13 selectively occupies the separated position shown in FIG. 2 and the pressed position shown in FIG.
[0049]
A switching member 10 for switching the transport path of the paper P is disposed on the transport path of the paper P on the left side of the contact position between the plate cylinder 12 and the press roller 13. A switching member 10 made of a plate having substantially the same width as the plate cylinder 12 and the press roller 13 has a downstream end in the sheet conveying direction fixed to a support shaft rotatably supported by the apparatus main body 11, and a solenoid. When the 123 (see FIG. 9) is operated, the upstream end in the sheet transport direction formed into an acute angle in cross section is selectively set to a first position shown by a solid line in FIG. 1 and a second position shown by a two-dot chain line. Is positioned.
[0050]
When the switching member 10 occupies the first position, the leading end thereof is located close to the peripheral surface of the press roller 13 and at a position where it does not interfere with the clamper 19b on the plate cylinder 12, and when the switching member 10 occupies the second position. Is placed at a position where its tip is close to the peripheral surface of the plate cylinder 12. The surface-printed sheet PA that has passed between the plate cylinder 12 and the press roller 13 is guided to the sheet discharge section 6 when the switching member 10 occupies the first position, and the switching member 10 is moved to the second position. Is guided to the auxiliary tray 8 through the space between the guide plate 27 and the guide plate 56 fixed to the apparatus main body 11.
[0051]
In the upper right part of the apparatus main body 11, a plate making unit 3 is provided. The plate making unit 3 includes a master holding member 57, a platen roller 58, a thermal head 59, a cutting unit 60, a master stock unit 61, a tension roller pair 62, a reversing roller pair 63, and the like. The plate making section 3 performs plate making on a master 64 described later, and a divided plate-making master 65 having a first plate making image 65A and a second plate making image 65B as shown in FIG. 6, or a first plate making image as shown in FIG. A prepressed master 66 having a third prepress image 66A having an image amount area for two surfaces of 65A and a second prepress image 65B is created. The first plate making image 65A is formed at a position corresponding to the front surface region shown in FIG. 1 when the divided plate making master 65 is wound on the outer peripheral surface of the plate cylinder 12, and the second plate making image 65B is formed at the back surface region. It is formed at the corresponding position.
[0052]
The master holding member 57 is provided on each of a pair of side plates (not shown) of the plate making section 3, and is a core of a master roll 64a formed by winding a master 64 in which a thermoplastic resin film and a porous support are bonded together in a roll shape. Both ends of the portion 64b are rotatably and detachably supported.
[0053]
The platen roller 58 provided on the left side of the master holding member 57 is rotatably supported by a side plate (not shown) of the plate making section 3 and is rotationally driven by plate making driving means 124 including a stepping motor (see FIG. 9). A thermal head 59, which is located below the platen roller 58 and has a number of heating elements, is also attached to a side plate (not shown) of the plate making section 3, and the heating element surface is pressed against the platen roller 58 by the urging force of a urging means (not shown). Have been. The thermal head 59 selectively heats the heat generating element while contacting the thermoplastic resin film surface of the master 64, and performs hot-melt perforation on the master 64.
[0054]
A cutting unit 60 is provided on the left side of the platen roller 58 and the thermal head 59. The cutting means 60 having a fixed blade 60a fixedly mounted on a frame (not shown) of the plate making section 3 and a movable blade 60b movably supported by the fixed blade 60a rotates the movable blade 60b with respect to the fixed blade 60a. This is a well-known configuration that disconnects the master 64 by moving.
[0055]
A master stock unit 61 is provided below the cutting means 60 on the downstream side in the master transport direction. The master stock unit 61, which is a space for temporarily storing the divided masters 65 or 66, is partitioned by a plurality of plate members, and a suction fan (not shown) is provided at the innermost part. Have been. When the suction fan is operated, a negative pressure is generated inside the master stock unit 61 which is a sealed space, and the divided master master 65 or the master 66 which has been conveyed is the deepest part of the master stock unit 61. Stored for the department.
[0056]
A tension roller pair 62 is disposed between the cutting unit 60 and the master stock unit 61. A pair of tension rollers 62 each composed of a driving roller 62a and a driven roller 62b rotatably supported by a side plate (not shown) of the plate making unit 3 is driven by the driven roller 62b by a biasing means (not shown). The master 64 is held in pressure contact with the surface, and is conveyed while nipping the master 64 by rotating the drive roller 62 a by the plate making drive unit 124. The driving roller 62a has a peripheral speed set slightly higher than the peripheral speed of the platen roller 58, and a torque limiter (not shown) is provided inside the driving roller 62a. A predetermined tension is applied to the master 64.
[0057]
A reversing roller pair 63 composed of a driving roller 63a and a driven roller 63b rotatably supported by a side plate (not shown) of the plate making unit 3 is disposed downstream of the master stock unit 61 in the master transport direction. The reversing roller pair 63 nips and conveys the master 64 between a driving roller 63a that is rotationally driven by the plate making driving unit 124 and a driven roller 63b that is pressed against the driving roller 63a by an urging unit (not shown). A one-way clutch (not shown) is provided inside the driving roller 63a.
[0058]
A movable master guide plate (not shown) is provided between the tension roller pair 62 and the reversing roller pair 63. The movable master guide plate is swingably supported by a support member (not shown). A solenoid (not shown) controls the upper surface of the movable master guide plate to form a transfer path for the master 64 and the master 64 enters the master stock unit 61. It is selectively positioned to a retreat position which does not interfere.
[0059]
Below the plate making section 3, a sheet feeding section 4 is provided. The paper supply unit 4 includes a paper supply tray 67, a paper supply roller 68, a separation roller 69, a separation pad 70, a registration roller pair 71, and the like.
A paper feed tray 67 capable of stacking a large number of papers P on the upper surface is supported by the apparatus main body 11 so as to be vertically movable, and is moved up and down by paper feed drive means 125 (see FIG. 9) including a lifting means. A pair of side fences 72 movably supported by a rail member (not shown) in a sheet width direction orthogonal to the sheet conveyance direction are provided on an upper surface of the sheet supply tray 67 on which A3 size sheets P can be vertically placed. . A plurality of paper size detection sensors 73 for detecting the size of the stacked paper P are provided on the free end side of the paper feed tray 67.
[0060]
Above the paper feed tray 67, a paper feed roller 68 having a high friction resistance member on its surface is provided. The paper feed roller 68 is rotatably supported by a bracket (not shown) that is swingably supported by the apparatus main body 11, and is supplied with a predetermined pressing force when the paper feed tray 67 is lifted by a lifting means (not shown). The uppermost sheet P on the tray 67 is pressed. The paper feed roller 68 is driven to rotate by the paper feed drive unit 125.
[0061]
On the left side of the paper feed roller 68, a separation roller 69 and a separation pad 70 each having a high frictional resistance member on its surface are provided. The separation roller 69 is drivingly connected to the paper feed roller 68 via a timing belt 69a, and is rotated in the same direction in synchronization with the rotation of the paper feed roller 68. The separation pad 70 is pressed against the separation roller 69 by the urging force of an urging means (not shown).
[0062]
A registration roller pair 71 is disposed on the left side of the separation roller 69 and the separation pad 70. A registration roller pair 71 composed of a driving roller 71a and a driven roller 71b transmits the rotational driving force from the plate cylinder driving unit 121 by a driving force transmitting unit (not shown) such as a gear or a cam, so that the driving roller 71a The sheet P rotates at a predetermined timing synchronized with the driving roller 12 and is fed at a predetermined timing toward the printing unit 2 by the driven roller 71b pressed against the driving roller 71a.
[0063]
Paper feed guide plates 136 and 137 for guiding the conveyance of the paper P fed from the paper feeding unit 4 to the printing unit 2 are arranged on the upstream side and the downstream side of the registration roller pair 71 in the paper conveying direction, respectively. Have been. The paper feed guide plates 136 and 137 are fixed between side plates (not shown) of the apparatus main body 11, respectively.
[0064]
A plate discharging section 5 is provided at the upper left of the printing section 2. The plate discharging section 5 has an upper plate discharging member 74, a lower plate discharging member 75, a plate discharging box 76, a compression plate 77, and the like.
The upper plate discharging member 74 includes a driving roller 78, a driven roller 79, an endless belt 80, and the like. The driving roller 78 is rotationally driven clockwise in FIG. 80 moves in the direction of the arrow in FIG. The lower plate discharging member 75 has a driving roller 81, a driven roller 82, an endless belt 83, and the like, and transmits a driving force of a plate discharging driving unit 126 that rotationally drives the driving roller 78 by a driving force transmitting unit (not shown) such as a gear or a belt. As a result, the drive roller 81 is driven to rotate in the counterclockwise direction in the figure, whereby the endless belt 83 moves in the direction of the arrow in FIG. The lower plate discharging member 75 is provided movably by a moving unit (not shown) included in the plate discharging driving unit 126, and the endless belt 83 located at the position shown in the drawing and on the outer peripheral surface of the driven roller 82 is attached to the plate cylinder 12. And a position in contact with the outer peripheral surface.
[0065]
A plate discharging box 76 for storing the used master 64c therein is provided detachably with respect to the apparatus main body 11. A compression plate 77 that pushes the used master 64c carried by the upper plate discharging member 74 and the lower plate discharging member 75 into the inside of the plate discharging box 76 is vertically movably supported by the apparatus main body 11, and is included in the plate discharging driving means 126. It is moved up and down by lifting means (not shown).
[0066]
Below the plate discharging section 5, a paper discharging section 6 is provided. The paper discharge unit 6 includes a peeling claw 84, a paper discharge transport unit 85, a paper discharge tray 86, and the like.
A plurality of peeling claws 84 are arranged in the width direction of the plate cylinder 12, and are integrally attached to support shafts that are swingably supported by the apparatus main body 11. The plurality of peeling claws 84 are oscillated by claw oscillating means (not shown), and their ends are close to the peripheral surface of the plate cylinder 12 as shown in the figure, and their ends are used to avoid obstacles such as the clamper 19b. A position distant from the outer peripheral surface of the body 12 is selectively occupied. The not-shown claw swinging means transmits the driving force from the plate cylinder driving means 121 by the not-shown driving force transmitting means, and rocks the peeling claw 84 in synchronization with the rotation of the plate cylinder 12.
[0067]
The sheet discharge conveyance unit 85 disposed below the separation claw 84 and to the left of the switching member 10 includes a driving roller 87, a driven roller 88, an endless belt 89, a suction fan 90, and the like. A plurality of roller-shaped drive rollers 87 are attached at predetermined intervals to a support shaft (not shown) rotatably supported on a unit side plate (not shown), and are integrally rotated by sheet discharge drive means 127 (see FIG. 9). Is done. A plurality of driven rollers 88 are also provided at equal intervals with each drive roller 87 on a support shaft (not shown) rotatably supported by the same side plate, and an endless belt 89 is provided for each drive roller 87 and each corresponding driven roller 88. Has been passed over each. A suction fan 90 is provided below the driving roller 87, the driven roller 88, and the endless belt 89. The paper discharge transport unit 85 sucks the paper P onto each endless belt 89 by the suction force of the suction fan 90, and transports the printed paper PB in the direction of the arrow in FIG.
[0068]
A paper discharge tray 86 on which the printed paper PB conveyed by the paper discharge conveyance unit 85 is stacked has one end fence 91 movable in the paper conveyance direction and a pair of side fences movable in the paper width direction. 92.
[0069]
An image reading section 7 is provided at an upper portion of the apparatus main body 11. The image reading unit 7 includes a contact glass 93 on which a document is placed, a pressure plate 94 provided to be able to freely contact and separate from the contact glass 93, reflection mirrors 95, 96, 97, 98 for scanning and reading a document image, and a fluorescent lamp. 99, a lens 100 for focusing the scanned document image, an image sensor 101 such as a CCD for processing the focused image, a plurality of document size detection sensors 102 for detecting the size of the document, an image for storing the read image data It has a memory 135 and the like, and the reading operation of the document image is performed by the operation of the reading driving means 128 (see FIG. 9).
[0070]
As shown in FIG. 1, a dog 133 is attached to an outer surface of an end plate (not shown) constituting the plate cylinder 12, and a home position sensor 134 attached to the apparatus main body 11 near the periphery of the plate cylinder 12. Are arranged. The home position sensor 134 detects the dog 133 when the plate cylinder 12 occupies the position where the clamper 19b faces the press roller 13, and outputs a signal to a control unit 129 described later.
[0071]
FIG. 8 shows an operation panel of the duplex printing apparatus 1. In the figure, an operation panel 103 provided on the upper front surface of the apparatus main body 11 has a plate making start key 104, a print start key 105, a trial printing key 106, a continuous key 107, a clear / stop key 108, a numeric keypad 109, an enter key Key 110, a program key 111, a mode clear key 112, a print speed setting key 113, a four-way key 114, a paper size setting key 115, a paper thickness setting key 116, a two-sided printing key 117, a one-sided printing key 118, and a seven-segment LED. A display device 119, a display device 120 including an LCD, and the like are provided.
[0072]
The plate making start key 104 is pressed when the duplex printing apparatus 1 performs a plate making operation, and when the plate making start key 104 is pressed, a plate making operation is performed after a plate discharging operation and a document reading operation are performed. The operation is performed, and the duplex printing apparatus 1 enters a printing standby state. The print start key 105 is pressed when the duplex printing apparatus 1 performs a printing operation. The printing operation is performed when the printing start key 105 is pressed after the duplex printing apparatus 1 enters a print standby state and various printing conditions are set. Done. The trial printing key 106 is pressed when the duplex printing apparatus 1 performs trial printing, and only one sheet is printed by pressing the trial printing key 106 after various conditions are set. The continuous key 107 is pressed before pressing the plate making start key 104 when performing the plate making operation and the printing operation continuously. After the continuous key 107 is pressed, the printing condition is input, and then the plate making start key 104 is pressed. Then, the printing operation is performed subsequent to the plate discharging operation, the original reading operation, and the plate making operation.
[0073]
The clear / stop key 108 is depressed when stopping the operation of the duplex printing apparatus 1 or when clearing the numerical value, and the numeric keypad 109 is used for numerical input. An enter key 110 is pressed when setting a numerical value or the like at the time of various settings, a program key 111 is pressed to register a frequently-used operation or calling it, and a mode clear key 112 is used to clear various modes and initialize the mode. Pressed to return to the state. The print speed setting key 113 is depressed when setting the print speed prior to the printing operation. When the user wants to obtain a darker image or when the ambient temperature is low, the print speed is reduced, and when the user wants to obtain a thinner image, When the ambient temperature is high, the printing speed is set to be high. The four-way key 114 has an up key 114a, a down key 114b, a left key 114c, and a right key 114d, and is depressed when adjusting an image position when editing an image or when selecting a numerical value or an item at the time of various settings. Is done.
[0074]
The paper size setting key 115 is pressed to arbitrarily input a paper size, and the paper size input by the paper size setting key 115 has priority over the paper size detected by the paper size detection sensor 73. The paper thickness setting key 116 is depressed when inputting the thickness of the paper P prior to double-sided printing. In this embodiment, one of three types of “plain paper”, “thin paper”, and “thick paper” is selected. It has a configuration.
[0075]
When the two-sided printing key 117 is pressed before pressing the plate making start key 104 when the two-sided printing apparatus 1 performs the two-sided printing operation, when the two-sided printing key 117 is pressed, the LED 117a disposed near the key is turned on to turn on the operator. Indicates that the mode is the duplex printing mode. When the double-sided printing key 117 is pressed, the input of the plate making start key 104 is rejected only after the thickness of the paper P to be used has been input by the paper thickness setting key 116. Similarly to the two-sided printing key 117, the one-sided printing key 118 is pressed before the start key 104 is pressed when the two-sided printing apparatus 1 performs the one-sided printing operation, and is arranged near the one-sided printing key 118 when the one-sided printing key 118 is pressed. The LED 118a lights up to indicate to the operator that the single-sided printing mode is set. In the double-sided printing apparatus 1, the LED 118a is turned on in the initial state, and the single-sided printing mode is set.
[0076]
The display device 119 composed of 7-segment LEDs mainly displays numbers such as the number of prints. The display device 120 composed of an LCD has a hierarchical display structure. By pressing selection setting keys 120a, 120b, 120c, and 120d provided below the display device 120, various modes such as scaling and position adjustment can be changed. And setting in each mode is possible. Further, the display device 120 displays the state of the duplex printing apparatus 1 such as “can make and print” as shown in the figure, as well as alarms such as plate making or discharging jam, paper feeding or discharging jam, and printing paper. A supply instruction of a supply of a master, ink, etc. is also displayed.
[0077]
FIG. 9 is a block diagram of a control unit used in the duplex printing apparatus 1. In the figure, a control unit 129 is a well-known microcomputer having a CPU 130, a ROM 131, and a RAM 132 therein, and is provided inside the apparatus main body 11.
[0078]
Based on various signals from the operation panel 103, detection signals from various sensors provided in the apparatus main body 11, and an operation program called from the ROM 131, the CPU 130 executes the printing unit 2, the plate making unit 3, the sheet feeding unit 4, The operation of the solenoids 123 and the driving member 122 provided in the sheet feeding unit 9, the sheet reading unit 6, and the image reading unit 7, the solenoid 33 and the conveyance member driving motor 122 provided in the sheet re-feeding unit 9, and the switching member 10. And controls the operation of the entire duplex printing apparatus 1. An operation program for the entire duplex printing apparatus 1 is stored in the ROM 131, and the operation program is appropriately called by the CPU. The RAM 132 has a function of temporarily storing the calculation result of the CPU 130, a function of storing data signals and ON / OFF signals set and input from various keys and various sensors on the operation panel 103 as needed, and the like. The control unit 129 also grasps the position of the plate cylinder 12 based on a home position signal from the home position sensor 134 and a signal from an encoder (not shown) provided in the plate cylinder driving unit 121.
[0079]
The operation of the duplex printing apparatus 1 without the paper receiving plate 40, which is a feature of the present invention, based on the above-described configuration will be described below.
The operator places the paper P used for printing on the paper feed tray 67, opens the pressure plate 94, places the document to be printed on the contact glass 93, and then closes the pressure plate 94 again. Then, after setting the plate making conditions using various keys on the operation panel 103, the user presses the double-sided printing key 117 or the single-sided printing key 118 to set the printing mode and presses the plate making start key 104. First, a case in which one-sided printing is performed by pressing the one-sided printing key 118 will be described.
[0080]
After confirming that the mode is the single-sided printing mode by turning on the LED 118a, the operator presses the plate making start key 104. When the plate-making start key 104 is pressed, a paper size detection signal is sent from the paper size detection sensor 73 and a document size detection signal is sent from the document size detection sensor 102 to the control unit 129. Compare each signal. At this time, if the paper size and the document size are the same, the image reading operation is immediately performed. If the paper size and the document size are different, the control unit 129 displays the fact on the display device 120 and warns the operator. Prompt. When the paper size and the document size are different, the enlargement or reduction of the magnification may be automatically performed by a command from the control unit 129 so that the document size and the image size are matched.
[0081]
When the plate making start key 104 is pressed, the image reading section 7 performs an operation of reading a document image. The reading of the original image is performed by reflecting the reflected light exposed by the fluorescent lamp 99 by each of the reflecting mirrors 95, 96, 97, 98. The read original image is converged by the lens 100, and then the image sensor 101. And is photoelectrically converted. The photoelectrically converted electric signal is input to an A / D converter (not shown) in the apparatus main body 11, and then stored in the image memory 135 as an image data signal.
[0082]
In parallel with the image reading operation of the image reading unit 7, the plate discharging unit 5 performs a plate discharging operation of separating the used master from the outer peripheral surface of the plate cylinder 12. When the plate making start key 104 is depressed, the plate cylinder 12 starts rotating. When the plate cylinder 12 reaches the home position shown in FIG. 1, the dog 133 is detected by the home position sensor 134, and the control means 129 is output from the home position sensor 134. The home position signal is sent to. The control means 129 having received the home position signal measures the number of pulses generated by an encoder (not shown) with the home position as a base point, and the leading end of the used master wound on the outer peripheral surface of the plate cylinder 12 is driven by the driven roller 82. When it is determined that the predetermined plate discharging position corresponding to the endless belt 83 located on the outer peripheral surface has been reached, the operation of the plate cylinder driving means 121 is stopped.
[0083]
When the plate cylinder driving unit 121 is stopped and the plate cylinder 12 stops at a predetermined plate discharging position, the plate cylinder driving unit 121 and the plate discharging driving unit 126 operate to drive the respective drive rollers 78 and 81 to rotate, and the lower plate discharging member. 75 moves to the plate cylinder 12 side, and the endless belt 83 located on the outer peripheral surface of the driven roller 82 comes into contact with the used master 64 c on the plate cylinder 12. Then, the used master 64c picked up from the outer peripheral surface of the plate cylinder 12 by the rotation of the plate cylinder 12 and the movement of the endless belt 83 is nipped and conveyed by the lower plate discharging member 75 and the upper plate discharging member 74, and Peeled from the outer peripheral surface. The used master 64 c that has been peeled is discarded in the plate discharge box 76, and then compressed by the compression plate 77.
[0084]
After all the used masters 64c have been peeled off from the outer peripheral surface, the plate cylinder 12 continues to rotate, and the clamper 19b rotates to a predetermined plate supply standby position located at the upper right and stops. When the plate cylinder 12 stops at the plate feeding standby position, the opening / closing means (not shown) operates to open the clamper 19b, and the duplex printing apparatus 1 enters a plate feeding standby state.
[0085]
In parallel with the plate discharging operation, the plate making section 3 performs a plate making operation. When the plate-making start key 104 is pressed, the platen roller 58, the tension roller pair 62, and the reversing roller pair 63 are respectively driven to rotate, and the master 64 is pulled out from the master roll 64a. At this time, the movable master guide plate (not shown) is positioned at the transport position. When the master 64 is pulled out and its image forming area reaches a position corresponding to the heating element of the thermal head 59, the image data signal stored in the image memory 135 is called after being subjected to image processing, and is not shown. The third plate-making image 66A is formed on the surface of the thermoplastic resin film of the master 64 by causing the thermal head driver to selectively heat each heating element of the thermal head 59. When the master 64 is conveyed while making a plate and its leading end is held between the pair of reversing rollers 63, the movable master guide plate (not shown) is moved to the retracted position and the rotation of the pair of reversing rollers 63 is stopped.
[0086]
After the rotation of the reversing roller pair 63 is stopped, the platen roller 58 and the tension roller pair 62 continue to rotate, and the plate-making master 66 made by the thermal head 59 is stored in the master stock unit 61. When the pair of reversing rollers 63 is stopped, the suction fan (not shown) provided in the master stock unit 61 is operated, and the plate-making master 66 is favorably stored in the master stock unit 61 by being sucked by the suction fan (not shown). Is done.
[0087]
During the plate making operation described above, when the plate discharging operation is completed and the duplex printing apparatus 1 enters the plate feeding standby state, the pair of reversing rollers 63 starts rotating, and the plate made master 66 stored in the master stock unit 61 is moved to the stage. The sheet is transported between the section 19a and the opened clamper 19b. Then, when the leading end of the pre-made master 66 is transported to a predetermined position where it can be clamped by the clamper 19b, an opening / closing means (not shown) is operated to close the clamper 19b, and the pre-made master 66 moves its leading end to the stage 19a. And the clamper 19b are held on the outer peripheral surface of the plate cylinder 12.
[0088]
Thereafter, the plate cylinder 12 is intermittently driven to rotate clockwise in FIG. 1 to perform the operation of winding the plate-making master 66 around the plate cylinder 12. At this time, the rotation of the reversing roller pair 63 is stopped, and the driving roller 63a is rotated by the one-way clutch (not shown) provided therein as the plate-making master 66 is pulled out. When the image data signal from the image memory 135 is interrupted, the operation of the thermal head 59 is stopped, and when the plate-making master 66 for one plate is conveyed, the platen roller 58, the tension roller pair 62, and the reversing roller pair 63 are moved. The rotation is stopped, and the cutting means 60 is operated, so that the plate-making master 66 is cut. The cut master 66 is pulled out of the plate making unit 3 by the rotation of the plate cylinder 12, and the plate cylinder 12 rotates to the home position and stops, thereby completing the plate making operation and the plate feeding operation.
[0089]
The printing operation is performed subsequent to the printing operation. When the plate cylinder 12 stops at the home position, the solenoid 123 is operated to position the switching member 10 at the first position. Then, the press roller engaging means (not shown) is operated, and the stepping motor 52 is operated to operate the step cam 49. Is rotated to bring the cam portion 49b into contact with the cam follower 48c. As a result, after the movable arm 48 is swung about the support shaft 48a and the cam shaft 44 is moved to a position where the cam plate 43A can be brought into contact with the cam follower 41, the operation of the press roller locking means (not shown) is performed. Is released.
[0090]
Thereafter, the sheet feeding roller 68, the separation roller 69, the driving roller 87, and the suction fan 90 are respectively driven, and the plate cylinder 12 is driven to rotate at a low speed in the clockwise direction in FIG. The topmost sheet of the paper P is pulled out and its leading end is held between the registration roller pair 71. Then, at a predetermined timing when the leading end of the image area of the third plate making image 66A in the plate cylinder rotating direction of the plate-making master 66 wound on the plate cylinder 12 reaches a position corresponding to the press roller 13, the drive roller 71a is turned on. The rotationally driven and pulled out sheet P is fed between the plate cylinder 12 and the press roller 13.
[0091]
In synchronization with the rotation of the plate cylinder 12, the cam shaft 44 and the multi-stage cam 43 provided integrally therewith are rotationally driven by the press roller contact / separation mechanism 55, and can come into contact with the cam follower 41 as described above. The cam plate 43A, which has been moved to the position, causes the convex portion to separate from the cam follower 41 at the predetermined timing. As a result, the press roller 13 presses its peripheral surface against the outer peripheral surface of the plate cylinder 12 by the urging force of the printing pressure spring 42, and the sheet P fed by the registration roller pair 71 is wound around the plate cylinder 12. Pressed by master 66. By this pressing operation, the press roller 13, the sheet P, the plate-making master 66, and the plate cylinder 12 are pressed against each other, and the ink supplied to the inner peripheral surface of the plate cylinder 12 by the ink roller 16 oozes out from the opening of the plate cylinder 12. After filling the porous support plate (not shown) and the mesh screen (not shown) constituting the plate cylinder 12, and the porous support of the plate-made master 66 wound around the plate cylinder 12, the perforated portion of the plate-made master 66 is removed. The image is transferred to the sheet P via a so-called printing plate, and so-called printing is performed.
[0092]
The sheet P on which an image corresponding to the third plate-making image 66A is printed by printing is turned into a printed sheet PB and guided to the sheet discharge conveyance unit 85 by the switching member 10 occupying the first position. The exfoliation claw 84 separates the leading end from the master 66 on the outer peripheral surface of the plate cylinder. The peeled printed paper PB falls downward, is sent to the paper discharge transport unit 85, and is transported to the left while being attracted to the upper surface of the endless belt 89 by the suction force of the suction fan 90, and is discharged to the paper discharge tray. 86. After that, the plate cylinder 12 rotates again to the home position and stops, and the plate attaching operation is completed, and the duplex printing apparatus 1 enters a printing standby state.
[0093]
After the duplex printing apparatus 1 is in the printing standby state, the test printing is performed when the test printing key 106 is pressed after the printing conditions are input using the printing speed setting key 113 and various keys on the operation panel 103. When the test print key 106 is pressed, the plate cylinder 12 is driven to rotate at the set printing speed, and one sheet of paper P is fed from the paper feed unit 4. The fed sheet P is temporarily stopped by the pair of registration rollers 71 and then fed at the same timing as the time of printing, and is pressed by the press roller 13 against the master 66 on the outer peripheral surface of the printing drum. The printed sheet PB on which the image has been printed is guided to the sheet discharge unit 6 by the switching member 10, then separated from the plate-made master 66 on the outer peripheral surface of the plate cylinder by the separation claw 84, and is conveyed by the sheet discharge conveyance unit 85. The paper is then discharged onto the paper discharge tray 86.
[0094]
When the print start key 105 is pressed after the number of prints is input by the numeric keypad 109 after the position or density of the image is confirmed by the trial printing, the paper P is continuously fed from the paper feeding unit 4 and the trial printing is performed. The printing operation is performed under the same conditions as described above. Then, when the set number of prints is exhausted, the plate cylinder 12 stops at the home position, and the duplex printing apparatus 1 returns to the printing standby state.
[0095]
Next, a case in which double-sided printing is performed by pressing the double-sided printing key 117 will be described. After confirming that the mode is the duplex printing mode by turning on the LED 117a, the operator presses the paper thickness setting key 116 to set the thickness of the paper P to be used. In this double-sided printing mode, if the paper thickness setting key 116 is not pressed, the input of the plate making start key 104 is rejected, and if the paper thickness setting key 116 is not pressed but the plate making start key 104 is pressed, The means 129 causes the display device 120 to display an indication that the thickness of the sheet is to be set. In this embodiment, when the thickness of the paper P set by the paper thickness setting key 116 is “plain paper” or “thin paper”, the input of the plate making start key 104 is permitted, and when “thick paper” is set. In order to prevent the paper P from being jammed, input of the plate making start key 104 is rejected, and the control means 129 causes the display device 120 to display a warning that the correct paper must be set.
[0096]
When a sheet P that is “plain paper” or “thin paper” is set on the sheet feeding tray 67 and the sheet thickness based on the sheet P is set by the sheet thickness setting key 116, the plate making start key 104 is pressed. As in the case of single-sided printing, a sheet size detection signal and a document size detection signal are sent from the sensors 73 and 102 to the control unit 129, respectively, and the control unit 129 compares the input signals. In this embodiment, since the maximum paper size that can be printed by the plate cylinder 12 is A3 size, the paper size that can be used in duplex printing is up to A4 landscape. As a result of comparing the document size and the paper size, if the two sizes are the same, the image reading operation is immediately performed. If the two sizes are different, the control unit 129 displays a warning on the display device 120 as a warning. Call attention to the operator. When the paper size is different from the document size, the size of the document is matched with the image size by automatically enlarging or reducing the size in response to a command from the control unit 129. A configuration may be adopted in which a procedure such as rotation is displayed to assist the operator's operation. If the paper size is larger than A4 landscape, the control unit 129 may display on the display device 120 a message indicating that double-sided printing is prohibited and single-sided printing is encouraged.
[0097]
When the plate making start key 104 is pressed, the image reading section 7 reads the first document image in the same manner as in the case of single-sided printing. The read document image is stored in the image memory 135 as a first image data signal. When the reading operation of the first document is completed and the image data signal is stored in the image memory 135, the control unit 129 displays on the display device 120 a message indicating that the second document should be set. Let The operator opens the pressure plate 94 according to this display, removes the first document from the contact glass 93, places the second document, and closes the pressure plate 94 again. When a sensor (not shown) detects that the pressure plate 94 is closed, and when another sensor (not shown) detects that a document is present on the contact glass 93, the reading operation of the second document is performed similarly to the first document. Is The read document image is stored in the image memory 135 as a second image data signal.
[0098]
In this embodiment, the document reading operation in the single-sided printing mode and the double-sided printing mode is configured such that the operator opens and closes the pressure plate 94 and sets the document to be read on the contact glass 93, but the ADF is used. A configuration in which the original is automatically conveyed onto the contact glass 93 or a configuration in which image data is taken in from an external device (not shown) may be adopted. Further, in the double-sided printing mode, one document may be inverted and conveyed, and two pages of image data may be obtained from the front and back surfaces.
[0099]
In parallel with the image reading operation in the image reading unit 7, the plate discharging operation is performed in the plate discharging unit 5 in the same manner as in single-sided printing. The plate cylinder 12 from which the used master 64c has been peeled off from the outer peripheral surface is stopped at the plate feeding standby position, and the clamper 19b is opened by opening / closing means (not shown). The plate making section 3 performs a plate making operation in parallel with the plate discharging operation. The plate making operation is performed in the same procedure as in the single-sided printing mode, but the master 64 has a first plate making image 65A and a second plate making image 65B formed on its thermoplastic resin film surface. At this time, the respective images 65A and 65B are prepressed such that a predetermined blank portion S is provided between the first prepress image 65A and the second prepress image 65B as shown in FIG. The predetermined blank portion S is provided at a position corresponding to the intermediate area shown in FIG. 1 when the divided master plate master 65 is wound on the outer peripheral surface of the plate cylinder 12.
[0100]
The divided master plate 65 on which the images 65A and 65B are formed is stored in the master stock unit 61. When the plate discharging operation is completed and the duplex printing apparatus 1 is in the plate feeding standby state, the master 65 is divided by the operation of the reversing roller pair 63. The prepressed master 65 is transported between the stage section 19a and the opened clamper 19b. Thereafter, the plate cylinder 12 is intermittently rotated in the same manner as in the single-sided printing mode, and the divided master plate master 65 is wound around the plate cylinder 12. Then, when all of the two image data are sent from the image memory 135, the cutting means 60 is operated to cut the divided master plate master 65. The cut divided master plate master 65 is pulled out of the plate making section 3 by the rotation of the plate cylinder 12, the plate cylinder 12 stops at the home position, and the plate making operation and the plate feeding operation are completed.
[0101]
The printing operation is performed subsequent to the printing operation. When the plate cylinder 12 stops at the home position, the stepping motor 52 is operated to rotate the step cam 49, and at the same time, the press roller locking means (not shown) is operated to bring the cam portion 49a into contact with the cam follower 48c. As a result, the moving arm 48 is swung about the support shaft 48a, and the cam shaft 44 is moved to a position where the cam plate 43B can come into contact with the cam follower 41. Is released.
[0102]
Thereafter, the sheet supply roller 68, the separation roller 69, the respective drive rollers 36 and 87, and the respective suction fans 39 and 90 are respectively driven, and the plate cylinder 12 is rotated at a low speed in the clockwise direction in FIG. The first sheet P is pulled out from above 67, and the leading end thereof is held between the pair of registration rollers 71. When the clamper 19b passes through the position corresponding to the switching member 10, the solenoid 123 is operated to position the switching member 10 at the second position, and thereafter, the divided master plate 65 wound around the plate cylinder 12 is moved. The driving roller 71a is driven to rotate at a predetermined timing at which the leading end of the image area of the first plate making image 65A in the plate cylinder rotating direction reaches a position corresponding to the press roller 13, so that the first sheet P pulled out. Is fed between the plate cylinder 12 and the press roller 13.
[0103]
At the predetermined timing, the cam plate 43B, which has been moved to a position where it can come into contact with the cam follower 41, releases its convex portion from the cam follower 41, and the press roller 13 presses the peripheral surface thereof by the urging force of the printing pressure spring 42. It is pressed against the outer peripheral surface of the body 12. As a result, the press roller 13, the first sheet P, the first plate-making image 65 </ b> A forming portion of the divided plate-making master 65 and the plate cylinder 12 were pressed against each other, and were supplied to the inner peripheral surface of the plate cylinder 12 by the ink roller 16. After the ink seeps out of the opening of the plate cylinder 12 and fills the porous support plate (not shown) and the mesh screen (not shown) wound around the plate cylinder 12, and the porous support of the divided master plate 65, The plate is transferred onto the first sheet P via the perforated portion of the plate making image 65A, and the portion of the divided plate making master 65 where the first plate making image 65A is formed is printed.
[0104]
An image corresponding to the first plate-making image 65A is printed on the surface thereof by printing, and the first sheet P, which has become the surface-printed sheet PA, is divided from one end by the leading end of the switching member 10 on the outer peripheral surface of the plate cylinder. While being separated from the plate-making master 65, the switching member 10 occupying the second position guides the sheet to the sheet re-feeding means 9. The surface-printed paper PA guided downward by the switching member 10 passes between the guide plates 27 and 56, and has one end thereof abutting on the end fence 8a, and is placed on the auxiliary tray 8. The front-printed paper PA conveyed onto the auxiliary tray 8 is conveyed in the direction of the arrow in FIG. 1 while being held by the endless belt 38 by the suction force of the suction fan 39, and is conveyed to the other end (when printing the first plate-making image 65A). The rear end) is brought into contact with the re-feed positioning member 24. At this time, the sensor 8c detects the other end of the front-side printed paper PA, and a detection signal from the sensor 8c is output to the control unit 129. The operation of the fan 39 is stopped.
[0105]
While the first sheet P is being guided on the auxiliary tray 8, the plate cylinder 12 continues to rotate, and when the press roller 13 finishes contact with the surface area of the plate cylinder 12, the projection of the cam plate 43B becomes convex. The part occupies the separated position by abutting on the cam follower 41. By the function of the cam plate 43B, the back surface area of the plate cylinder 12 and the press roller 13 do not come into pressure contact with each other in a state where the sheet P is not present, and the transfer of the ink to the peripheral surface of the press roller 13 can be prevented. At this time, after the press roller locking means (not shown) is operated to hold the press roller 13 at the separated position, the stepping motor 52 is operated to rotate the step cam 49 and bring the cam portion 49b into contact with the cam follower 48c. As a result, the moving arm 48 is swung about the support shaft 48a, and the cam shaft 44 is moved to a position where the cam plate 43A can contact the cam follower 41.
[0106]
At substantially the same time as the above operation, the paper feed roller 68 and the separation roller 69 are driven, the second paper P is pulled out from the paper feed tray 67, and the leading end thereof is held between the registration roller pair 71. Then, the drive roller 71a is driven to rotate at the same predetermined timing as described above, and the second sheet P pulled out is fed between the plate cylinder 12 and the press roller 13.
[0107]
On the other hand, in the press roller contacting / separating mechanism 55, when the cam shaft 44 rotates to a position where the moved convex portion of the cam plate 43A can come into contact with the cam follower 41, the operation of the not-shown press roller locking means is released. At this time, the plate cylinder 12 rotating in synchronization with the cam shaft 44 occupies a position where the non-opening portion, which is a portion other than the front surface region, the back surface region, and the intermediate region, faces the press roller 13. Further, the solenoid 123 is operated until the surface area of the plate cylinder 12 passes through the portion facing the press roller 13 and the clamper 19b again occupies the position corresponding to the switching member 10, and the switching member 10 is moved to the second position. Displaced from a position to a first position.
[0108]
At a predetermined timing at which the second sheet P is fed by the pair of registration rollers 71, the cam plate 43A separates its convex portion from the cam follower 41, so that the press roller 13 is rotated by the urging force of the printing pressure spring 42. The surface is pressed against the outer peripheral surface of the plate cylinder 12. As a result, the press roller 13, the second sheet P, the first plate-making image 65 </ b> A forming portion of the divided plate-making master 65 and the plate cylinder 12 were pressed against each other, and were supplied to the inner peripheral surface of the plate cylinder 12 by the ink roller 16. The ink is transferred to the second sheet P through the opening of the plate cylinder 12, a porous support plate (not shown), a mesh screen (not shown), and a perforated portion of the first plate making image 65A.
[0109]
The second sheet P that has been printed with an image corresponding to the first plate-making image 65A and has become the printed sheet PB is guided to the sheet discharge transport unit 85 by the switching member 10 occupying the first position, and The peeling claw 84 separates one end of the master 65 from the divided master plate 65 on the outer peripheral surface of the plate cylinder. The peeled printed paper PB falls downward, is sent to the paper discharge transport unit 85, and is then discharged onto the paper discharge tray 86.
[0110]
After the second sheet P is fed by the pair of registration rollers 71, the leading end of the image area of the second plate making image 65 B in the plate cylinder rotation direction of the divided plate making master 65 is located at a position corresponding to the press roller 13. The solenoid 33 is actuated at a predetermined timing that is slightly earlier than the arrival, and the swing arm 32 swings clockwise in FIG. 2 around the support shaft 32a. As a result, the re-feed registration roller 23 is swung from the separated position to the pressure contact position, and the front-printed sheet PA that has been stopped with the other end in contact with the re-feed positioning member 24 is brought into contact with the plate cylinder 12. It comes into contact with the peripheral surface of the press roller 13 which is in contact therewith and is being driven to rotate.
[0111]
The surface-printed sheet PA abutted on the peripheral surface of the press roller 13 by the re-feed resist roller 23 is conveyed to the downstream side in the rotation direction by the rotational force of the press roller 13, and the sheet guide plate 31 and each roller 28 , 29, and 30 are conveyed toward the contact portion with the plate cylinder 12 in a state of being in close contact with the peripheral surface of the press roller 13. At this time, an image corresponding to the first plate-making image 65A is printed on the front surface of the paper PA on which the front surface has been printed. Therefore, the surface-printed paper PA that has once contacted the peripheral surface of the press roller 13 does not shift, and the occurrence of problems such as rubbing stains and thickening of image lines is prevented. Then, after the rear end and the intermediate area of the second sheet P have passed the position corresponding to the press roller 13, the front-printed sheet PA has a timing at which the front end of the back area reaches the position corresponding to the press roller 13. Is sent to a contact portion between the plate cylinder 12 and the press roller 13.
[0112]
As a result, the press roller 13, the surface-printed paper PA, the second plate-making image 65B forming portion of the divided plate-making master 65 and the plate cylinder 12 are pressed against each other, and the ink supplied by the ink roller 16 to the inner peripheral surface of the plate cylinder 12 is pressed. Is transferred to the back surface of the front-printed sheet PA through the opening of the plate cylinder 12, a porous support plate (not shown), a mesh screen (not shown), and a perforated portion of the second plate-making image 65B. Plate printing is performed on the portion where the second plate image 65B is formed.
[0113]
The first sheet of paper P, which is an image corresponding to the first plate-making image 65A on the front side and an image corresponding to the second plate-making image 65B on the back side, and has become a printed sheet PB, occupies the first position. The sheet is guided by the switching member 10 to the sheet discharge / conveyance unit 85, and is peeled off from one end of the master 65 on the outer peripheral surface of the plate cylinder by one end thereof by the peeling claw 84. The peeled printed paper PB falls downward, is sent to the paper discharge transport unit 85, and is then discharged onto the paper discharge tray 86, thereby completing the plate-attaching operation of the divided plate-making master 65 to complete the double-sided printing. The printing device 1 enters a printing standby state.
[0114]
At the time of the above-described printing, a predetermined blank portion S is provided between the first plate-making image 65A and the second plate-making image 65B of the divided plate-making master 65, and the divided plate-making master 65 is placed on the outer peripheral surface of the plate cylinder 12. Since the intermediate area is formed when the sheet P is wound, the rear end of the second sheet P sent from the sheet feeding unit 4 and the front end of the front-side printed sheet PA sent from the sheet re-feeding unit 9 Is prevented from being polymerized, and good printing can be performed. In addition, when the front side printed paper PA is re-fed from the re-feeding means 9, the ink from the front side printed paper PA is re-applied on the surface of the press roller 13 by contacting the printing surface of the front side printed paper PA. Although the ink is transferred, the peripheral surface of the press roller 13 has ink repellency and the cleaning roller 26 cleans the peripheral surface of the press roller 13. Is reduced, and the removal of the re-transferred ink from the peripheral surface of the press roller 13 is promoted, so that the re-transfer of the ink from the press roller 13 to the back surface of the paper P can be prevented during the following printing.
[0115]
After the duplex printing apparatus 1 is in the printing standby state, when the test printing key 106 is pressed after the printing conditions are input using the printing speed setting key 113 and various keys on the operation panel 103, the test printing is performed. Even when the test print key 106 is depressed, the control means 129 causes the display device 120 to display a message to the effect that the thickness of the paper should be set, and when "thick paper" is set, the input of the test print key 106 is performed. Is rejected and a warning is displayed on the display device 120 stating that correct paper is set.
[0116]
When the test printing key 106 is pressed, the plate cylinder 12 is driven to rotate at the set printing speed after the cam shaft 44 is moved to a position where the cam plate 43B can come into contact with the cam follower 41, as in the case of plate printing. Then, the switching member 10 is positioned at the second position in the same manner as at the time of printing. After the rotation of the plate cylinder 12, the first sheet P is fed from the sheet feeding unit 4, and the fed first sheet P is temporarily stopped by the registration roller pair 71, and is the same as at the time of printing. It is fed at the timing, and is pressed against the first plate-making image 65A of the divided plate-making master 65 by the press roller 13. An image corresponding to the first plate-making image 65A is printed on the front surface, and the first sheet P that has become the surface-printed sheet PA is separated from the divided plate-making master 65 on the plate cylinder outer peripheral surface by the switching member 10. It is guided to the auxiliary tray 8. The front-printed sheet PA conveyed onto the auxiliary tray 8 is stopped by the suction force of the suction fan 39 while being held on the endless belt 38 with the other end abutting the re-feed positioning member 24.
[0117]
Thereafter, the press roller locking means (not shown) is activated to hold the press roller 13 at the separated position, and the cam 49 is rotated to rotate the cam shaft 43 to a position where the cam plate 43A can contact the cam follower 41. After the movement, the operation of the not-shown press roller locking means is released. The switching member 10 is displaced from the second position to the first position until the clamper 19b occupies a position corresponding to the switching member 10 again. Almost simultaneously with this operation, the second sheet P is fed from the sheet feeding unit 4, and the fed second sheet P is temporarily stopped by the registration roller pair 71, and then the first sheet P is fed. It is fed to the printing unit 2 at the same timing as P.
[0118]
The fed second sheet P is pressed against the first plate-making image 65A of the divided plate-making master 65 by the oscillating press roller 13, and an image corresponding to the first plate-making image 65A is printed on the surface and printed. The second sheet P, which has become the sheet PB, is guided to the sheet discharge conveyance unit 85 by the switching member 10 occupying the first position. The printed paper PB is peeled off from the divided plate-making master 65 by the peeling claw 84, falls downward, is conveyed by the paper discharge conveyance unit 85, and is discharged onto the paper discharge tray 86.
[0119]
After the second sheet P is fed by the pair of registration rollers 71, the solenoid 33 is actuated at the same timing as when printing is performed, and the re-feed registration roller 23 is displaced from the separated position to the press-contact position. The front-printed paper PA temporarily stopped on the sheet 8 comes into contact with the peripheral surface of the rotating press roller 13. The front surface printed paper PA is conveyed by the rotational force of the press roller 13, and is conveyed to the printing unit 2 by the re-feed guide member 22 while being in close contact with the peripheral surface of the press roller 13.
[0120]
The conveyed front surface printed paper PA is pressed against the second plate-making image 65B of the divided plate-making master 65 by the oscillating press roller 13, and the image corresponding to the second plate-making image 65B is transferred to the back surface. An image corresponding to each of the plate making images 65A and 65B is printed on both sides, and the first sheet P that has become a printed sheet PB is guided to the sheet discharge conveyance unit 85 by the switching member 10. Thereafter, the printed paper PB is peeled off from the divided plate-making master 65 by the peeling claw 84, conveyed by the paper discharge conveyance unit 85 and discharged onto the paper discharge tray 86, thereby completing the test printing.
[0121]
The position or density of the image is confirmed by trial printing, and when the print start key 105 is pressed after the number of prints is input using the numeric keypad 109, a printing operation is performed. Even when the print start key 105 is pressed, the control means 129 causes the display device 120 to display a message to the effect that the thickness of the paper must be set, and when "thick paper" is set, the input of the print start key 105 is performed. Is rejected and a warning is displayed on the display device 120 stating that correct paper is set. In the present embodiment, a case where N sheets are input as the number of prints will be described.
[0122]
When the print start key 105 is depressed, the cam shaft 44 is moved to a position where the cam plate 43B can be brought into contact with the cam follower 41 in the same manner as at the time of plate printing and test printing, and at the set printing speed. The plate cylinder 12 is driven to rotate, and the switching member 10 is positioned at the second position in the same manner as in plate printing and test printing. After the rotation of the plate cylinder 12, the first sheet P is fed from the sheet feeding unit 4, and the fed first sheet P is temporarily stopped by the pair of registration rollers 71, and then has the same timing as in trial printing. Sent by The first sheet P is pressed against the first plate-making image 65A of the divided plate-making master 65 by the press roller 13, so that an image corresponding to the first plate-making image 65A is printed on its surface, and the first sheet P The printed paper PA is obtained. The front-printed sheet PA is guided by the switching member 10 occupying the second position and is conveyed onto the auxiliary tray 8, and is stopped while the other end thereof is in contact with the re-feed positioning member 24.
[0123]
After that, the press roller locking means (not shown) is operated to hold the press roller 13 at the separated position, and the cam shaft 44 is moved to a position where the cam plate 43A can abut on the cam follower 41, and then, not shown. The operation of the press roller locking means is released. Almost simultaneously with this operation, the second sheet P is fed from the sheet feeding unit 4, and the second sheet P is temporarily stopped by the registration roller pair 71 and then at the same timing as the first sheet P. It is fed to the printing unit 2. The switching member 10 is positioned at the first position to avoid collision with the clamper 19b, and is then positioned again at the second position after passing through the clamper 19b.
[0124]
The fed second sheet P is pressed by the press roller 13 against the first plate-making image 65A of the divided plate-making master 65, and an image corresponding to the first plate-making image 65A is printed on the front surface. After the printed sheet PA has been formed, the sheet PA is guided by the switching member 10 occupying the second position, and is conveyed onto the auxiliary tray 8. At this time, the solenoid 33 is actuated at the same timing as the time of the trial printing, and the first surface-printed sheet PA stopped on the auxiliary tray 8 is conveyed to the printing unit 2 by the rotational force of the press roller 13. After the rear end of the first surface-printed sheet PA has passed through the contact portion between the plate cylinder 12 and the press roller 13, the middle area of the plate cylinder 12 is the press roller. 13 is sent to the contact portion between the plate cylinder 12 and the press roller 13 at a timing when the back surface area passes through the position facing the press roller 13 and the press roller 13, and the press roller 13 causes the second plate-making image of the divided plate-making master 65. By being pressed against the second plate 65B, an image corresponding to the second plate making image 65B is printed on the back surface, and the printed sheet PB is obtained.
[0125]
During the operation described above, the solenoid 123 is operated just before the intermediate region of the plate cylinder 12 occupies the position facing the press roller 13, and the switching member 10 is displaced from the second position to the first position. As a result, the rear end (the other end) of the second surface-printed sheet PA guided by the switching member 10 passes through a slight gap between the lower surface 10 a of the switching member 10 and the peripheral surface of the press roller 13. The leading end (one end) of the first printed sheet PB guided on the auxiliary tray 8 and subsequently conveyed is guided to the sheet discharge conveying unit 85 along the upper surface 10 b of the switching member 10. . The first printed sheet PB is separated from the divided master plate 65 by the separation claw 84 and then conveyed by the sheet discharge conveyance unit 85 to be discharged onto the sheet discharge tray 86.
[0126]
Thereafter, the third sheet P is fed from the sheet feeding unit 4, and the third sheet P is temporarily stopped by the pair of registration rollers 71 and then printed at the same timing as the first and second sheets P. It is fed to the section 2. The switching member 10 is positioned at the first position to avoid collision with the clamper 19b, and is again positioned at the second position after passing through the clamper 19b. An image corresponding to the first plate-making image 65A is printed on the front surface of the fed third sheet P to become a front-printed sheet PA, and then guided to the auxiliary tray 8 by the switching member 10. Then, at a predetermined timing, the solenoid 33 is operated, and the second surface-printed sheet PA stopped on the auxiliary tray 8 is transported to the printing unit 2.
[0127]
The second surface-printed paper PA is sent to the contact portion between the plate cylinder 12 and the press roller 13 at the same timing as the first surface-printed paper PA, and the back surface corresponds to the second plate-making image 65B. The printed image is printed and becomes the second printed paper PB. The switching member 10 is displaced from the second position to the first position at the same timing as described above, and the rear end (the other end) of the third surface-printed sheet PA is connected to the lower surface 10 a of the switching member 10 and the press roller 13. Is guided on the auxiliary tray 8 through a small gap between the auxiliary tray 8 and the peripheral surface of the auxiliary tray 8. Subsequently, the leading end (one end) of the second printed sheet PB conveyed from above the auxiliary tray 8 is guided to the sheet discharge conveying unit 85 along the upper surface 10b of the switching member 10, and the two sheets are printed. After the printed paper PB is peeled off from the divided master plate master 65 by the peeling claw 84, it is conveyed by the paper discharge transport unit 85 and discharged onto the paper discharge tray 86.
[0128]
Hereinafter, the same printing operation as described above is performed up to the (N-1) th sheet. Then, the N-th sheet P is fed from the sheet feeding unit 4 and an image corresponding to the first plate-making image 65A is printed on the surface thereof, and is guided on the auxiliary tray 8 as the N-th surface-printed sheet PA. After that, the (N-1) -th surface-printed sheet PA has an image corresponding to the second plate-making image printed on the back surface thereof, and the (N-1) -th printed sheet PB is placed on the discharge tray 86 as the (N-1) -th printed sheet PB. , The press roller locking means (not shown) was activated to hold the press roller 13 at the separated position, and the cam shaft 44 was moved to a position where the cam plate 43C could contact the cam follower 41. Thereafter, the operation of the unillustrated press roller locking means is released. At this time, the switching member 10 maintains the state occupying the first position.
[0129]
The cam follower 41 can be brought into contact with the cam follower 41 at a first timing earlier than when the leading end of the image area of the second plate making image 65B in the plate cylinder rotating direction of the divided plate making master 65 reaches a position corresponding to the press roller 13. The cam plate 43C, which has been moved to the position, disengages its convex portion from the cam follower 41, and the press roller 13 presses the peripheral surface of the cam plate 43 against the outer peripheral surface of the plate cylinder 12 by the urging force of the printing pressure spring. Thereafter, the solenoid 33 is actuated at a second timing slightly earlier than when the leading end of the image area of the second plate making image 65B in the plate cylinder rotation direction of the divided plate making master 65 reaches the position corresponding to the press roller 13, and the rocking is performed. The moving arm 32 is swung clockwise in FIG. 2 around the support shaft 32a. As a result, the re-feed resist roller 23 is swung from the separated position to the pressure contact position, and the N-th surface-printed sheet PA that has been stopped with the other end in contact with the re-feed positioning member 24 is moved to the plate. It is in contact with the peripheral surface of the press roller 13 which is in contact with the body 12 and is being driven and rotated.
[0130]
The N-th front side printed sheet PA is sent to the contact portion between the plate cylinder 12 and the press roller 13 at the same timing as the first front side printed sheet PA, and the back side corresponds to the second plate-making image 65B. The printed image is printed and becomes the N-th printed paper PB. The N-th printed sheet PB is guided along the upper surface 10b of the switching member 10 to the sheet discharging and conveying unit 85, and is separated by the separating claw 84 from the divided plate-making master 65 and then transferred by the sheet discharging and conveying unit 85. Is discharged onto the paper discharge tray 86. Thereafter, when the press roller 13 finishes contact with the back surface area of the plate cylinder 12, the convex portion of the cam plate 43C comes into contact with the cam follower 41 to occupy the separated position. By the action of the cam plate 43C, the surface area of the plate cylinder 12 and the press roller 13 do not come into pressure contact with each other in a state where the sheet P is not present, and the transfer of ink to the peripheral surface of the press roller 13 can be prevented. At this time, the press roller locking means (not shown) operates to hold the press roller 13 at the separated position, and then the plate cylinder 12 stops at the home position, the duplex printing apparatus 1 finishes the printing operation, and returns to the printing standby state. Become.
[0131]
At the time of the above-described printing, a predetermined blank portion S is provided between the first plate-making image 65A and the second plate-making image 65B of the divided plate-making master 65, and the divided plate-making master 65 is placed on the outer peripheral surface of the plate cylinder 12. Since the intermediate area is formed when the sheet is wound, the rear end of the sheet P sent from the sheet feeding unit 4 and the front end of the front-printed sheet PA sent from the sheet re-feeding unit 9 may overlap. The sheet P from the sheet feeding unit 4 can be reliably conveyed to the auxiliary tray 8 and the surface-printed sheet PA from the sheet re-feeding unit 9 can be reliably conveyed to the sheet discharge tray 86 by switching the switching member 10. Further, when the front-side printed paper PA is re-fed from the paper re-feeding means 9, the front-side printed paper PA comes into contact with the printing surface of the front-side printed paper PA and the outer peripheral surface of the plate cylinder 12 so that the front surface of the press roller 13 is printed. Although the ink from the paper PA and the ink from the outer peripheral surface of the plate cylinder are re-transferred, since the peripheral surface of the press roller 13 has ink repellency and the cleaning roller 26 cleans the peripheral surface of the press roller 13, the surface has been printed. The re-transferred ink from the paper PA to the peripheral surface of the press roller 13 is reduced, and the removal of the re-transferred ink from the peripheral surface of the press roller 13 is promoted. Can be prevented from being transferred again.
[0132]
According to the double-sided printing apparatus 1, the plate-making unit 3 creates a plate-made master 66 at the time of single-sided printing, winds it around the plate cylinder 12, feeds the sheet P from the sheet feeding unit 4, and presses the Since the master 13 is pressed against the plate cylinder 12, single-side printing can be performed in the same manner as a normal stencil printing apparatus without wastefully using the master 64. During double-sided printing, the plate making section 3 creates a divided plate-making master 65, winds it around the plate cylinder 12, feeds the first sheet P from the sheet feeding section 4, and presses the surface of After being pressed against the plate cylinder 12, the sheet is discharged onto the auxiliary tray 8, the second sheet P is fed from the paper supply unit 4, and this surface is pressed against the plate cylinder 12 by the press roller 13, and then the auxiliary tray 8, the first sheet PA having the front surface printed thereon is reversely fed by the re-feeding means 9, and the back surface thereof is pressed against the plate cylinder 12 by the press roller 13, and then discharged as the printed sheet PB. Since the sheet P is discharged onto the tray 86, both the front side image and the back side image printed on the paper P are formed by the ink transferred from the plate cylinder 12 by the press roller 13, so that a good double-sided printed matter can be obtained.
[0133]
Further, the configuration of the printing unit 2 includes a plate cylinder 12 and a press roller 13 having a smaller diameter than the plate cylinder 12, and the auxiliary tray 8 is disposed below a sheet discharge conveyance unit 85 configuring the sheet discharge unit 6. Therefore, the apparatus can be configured without significantly increasing the size as compared with a normal stencil printing apparatus for single-sided printing, and an increase in installation space can be suppressed.
[0134]
However, the close observation by the inventor of the present application has revealed that the above-described double-sided printing apparatus 1 has an important problem at the time of continuous printing. Hereinafter, the problem will be described.
[0135]
At the time of the above-described printing operation, when the second sheet P passes through the nip portion between the plate cylinder 12 and the press roller 13 and is sent to the auxiliary tray 8 as the second surface-printed sheet PA2, Then, the first surface-printed sheet PA1 is sent toward the nip between the plate cylinder 12 and the press roller 13. At this time, as shown in FIG. 10, one end of the front-printed paper PA2 comes into contact with one end of the front-printed paper PA1, thereby causing rubbing on one end and the back of the front-printed paper PA2. In addition, there is a problem that one end side of the front surface printed paper PA1 is rubbed and stained.
[0136]
Also, at this time, one end of the front side printed paper PA2 must be conveyed to the left in the figure, but one end thereof contacts one end of the front side printed paper PA1 conveyed to the right in the figure. The transport force of the paper P to the left in the drawing is canceled by the adhesive force of the ink on the surface-printed paper PA1 and the transporting force to the right in the drawing, and the front-printed paper PA2 stops at that location and is transported. There is a problem that a jam occurs.
[0137]
Further, FIG. 11 shows a state in which the plate cylinder 12 has been slightly rotated from the state shown in FIG. 10, and the sent front side printed sheet PA2 is in a state where the front side printed sheet PA1 is sent and there is no sheet. The suction force of the operating suction fan 39 causes the suction tray 39 to be attracted onto the auxiliary tray 8, and the frictional force of the endless belt 38 cancels the conveying force to the left in the figure. There is a problem that good conveyance of the printed paper PA2 is hindered and a conveyance jam occurs.
[0138]
In order to solve the above-mentioned problem, in the present invention, the sheet receiving plate 40 shown in FIG. Hereinafter, the paper receiving plate 40 used in the first embodiment of the present invention will be described.
[0139]
The paper receiving plate 40 having a U-shaped cross section has protrusions 40a, 40b, 40c, and 40d on both sides as shown in FIG. 3, and each of the protrusions 40a, 40b, 40c, and 40d is provided in the conveyance unit main body 35. Are fitted in elongated holes (not shown) formed in both side plates. A notch 40e is formed at one end of the paper receiving plate 40 as a fitting portion to which each end fence 8a can be fitted, and both sides of the paper receiving plate 40 extend to the other end. Each of the rack portions 40f is formed. The paper receiving plate 40 is disposed above the endless belts 38 and is spaced apart from the endless belts 38. The space between the lower surface and the endless belts 38 is such that the surface-printed paper PA is favorably conveyed on the endless belts 38. The predetermined interval is set so that it becomes possible.
[0140]
A stepping motor 138 having two pinions 139 on its output shaft 138a is mounted outside one side plate of the transport unit main body 35. The tip of the output shaft 138a is rotatably supported by the other side plate of the transport unit main body 35, and each pinion 139 is located at a position near both side plates of the transport unit main body 35 and at a position where it meshes with each rack portion 40f. It is arranged.
[0141]
In the vicinity of the stepping motor 138, a home position sensor 140 for detecting the home position of the sheet receiving plate 40 is provided. The home position sensor 140 is disposed at a position where the protrusion of the protrusion 40d can be detected, and a signal from the home position sensor 140 is output to the control unit 129.
[0142]
According to the above-described configuration, the paper receiving plate 40 is moved closer to the press roller 13 by the stepping motor 138 and receives one end of the front-printed paper PA2 conveyed from the printing unit 2, which is the first position which is the home position shown in FIG. 13 is reciprocated to selectively occupy the second position shown in FIG. 13 where the other end of the surface-printed paper PA2 placed farthest from the press roller 13 and placed on the upper surface thereof contacts each endless belt 38. You.
[0143]
The length of the paper receiving plate 40 in the paper transport direction is such that the paper receiving plate 40 occupies the second position, and the other end of the surface-printed paper PA2 on the paper receiving plate 40 is more endless than on the paper receiving plate 40. When the front-printed sheet PA2 falls on the belt 38 and is conveyed by the re-feeding conveyance unit 25, and the other end abuts on the re-feeding positioning member 24, one end of the front-printed paper PA2 is placed on the sheet receiving plate. The length is set to fall from above.
[0144]
By the function of the paper receiving plate 40, it is possible to prevent contact between the front-printed paper PA1 and the front-printed paper PA2 during continuous printing, and one end and the back of the front-printed paper PA2, and the front-printed paper. The occurrence of rubbing and dirt on one end side of PA1 can be prevented, and the occurrence of conveyance jam can be prevented by satisfactorily conveying surface-printed paper PA2.
[0145]
Further, the operation of the stepping motor 138 for reciprocating the paper receiving plate 40 is controlled by the control means 129 based on a signal from the sensor 8c, and when the front end of the front-printed paper PA1 is detected by the sensor 8c, the paper receiving plate is controlled. 40 may be configured to move from the second position to the first position. As a result, the front-printed sheet PA2 is reliably sucked and conveyed to the sheet re-feeding and conveying unit 25, the other end of the sheet PA2 comes into contact with the sheet re-feeding positioning member 24, and one end of the sheet PA2 drops from the sheet receiving plate 40. Since the movement of the paper 40 from the second position to the first position is performed, the interference between the paper receiving plate 40 and the front-printed paper PA2 can be reliably prevented, and the occurrence of paper conveyance jam is reliably prevented. can do.
[0146]
Further, since the sheet receiving plate 40 has a cutout 40e at one end thereof that can be fitted to each end fence 8a, one end of the front surface printed paper PA1 is formed between the end fence 8a and the sheet receiving plate 40. It is possible to prevent the sheet from getting into the gap, and it is possible to prevent the occurrence of a paper conveyance jam caused by this.
[0147]
FIGS. 14 and 15 show a sheet receiving plate 140 used in the second embodiment of the present invention. The sheet receiving plate 140 has a projection 140a similar to the projections 40a, 40b, 40c, and 40d in that the sheet receiving plate 140 does not have a cutout portion as a fitting portion as compared with the sheet receiving plate 40 shown in the first embodiment. , 140b, 140c, 140d and a rack portion 140f similar to the rack portion 40f, a pair of side fences 140e and two end fences 140g, and other configurations are the same. is there. In the second embodiment, the auxiliary tray 8 does not have the end fence 8a.
[0148]
Also in the sheet receiving plate 140, the length in the sheet conveying direction is such that the sheet receiving plate 140 occupies the second position, and the other end of the surface-printed sheet PA on the sheet receiving plate 40 is When the front-printed sheet PA falls from above onto the endless belt 38 and is conveyed by the re-feeding conveyance unit 25 and the other end contacts the re-feed positioning member 24, one end of the front-printed paper PA Is set to a length that falls from above the paper receiving plate 140.
[0149]
In other words, in FIG. 14, the distance L2 from the end of the sheet receiving surface of the sheet receiving plate 140 occupying the second position to the length L1 of the front side printed sheet PA in the sheet transport direction to the re-feed positioning member 24 is It is set to be large. The difference between L1 and L2 is suitably about 10 to 20 mm.
[0150]
With such a configuration, the front-printed paper PA is transported while its position in the width direction is determined by each side fence 140e and its position in the transport direction is determined by the end fence 140g. The skew and misalignment of the front-printed paper PA when the paper PA is dropped onto the tray 8 can be effectively prevented, and the occurrence of paper conveyance jam can be prevented.
[0151]
FIG. 16 shows a sheet receiving plate 141 used in the third embodiment of the present invention. The sheet receiving plate 141 has protrusions 141a, 141b, 141c, and 141d similar to the protrusions 140a, 140b, 140c, and 140d as compared with the sheet receiving plate 140 shown in the second embodiment, and a pair of side fences. It differs in that it has a pair of side fences 141e similar to 140e and two end fences 141f similar to two end fences 140g, and the other configuration is the same. In the third embodiment, the auxiliary tray 8 does not have the end fence 8a, and the driving mechanism of the sheet receiving plate 141 is different. Further, the arrangement position of the cleaning roller 26 is different, and the guide plate 27 is not provided.
[0152]
Each of the projections 140a, 140b, 140c, 140d is fitted into an elongated hole 35c formed on both side plates 35b of the transport unit main body 35 (see FIG. 17). The elongated hole 35b is formed to be inclined so as to be substantially the same as the falling path of the front-printed sheet PA that falls from the printing unit 2 onto the auxiliary tray 8.
[0153]
FIG. 17 shows a driving mechanism of the sheet receiving plate 141 in the third embodiment. A first pulley 142 and a second pulley 143 are rotatably supported near the position where the elongated hole 35c is formed between the side plates 35b, and an endless belt 144 is stretched between the pulleys 142 and 143. I have. Inside the endless belt 144, a guide roller 145 rotatably supported between both side plates 35b is disposed in contact with the endless belt 144. The endless belt 144 has a shape substantially similar to that of the elongated hole 35c below the elongated hole 35c. It is arranged to become. Further, a mounting portion 141g formed integrally with the sheet receiving plate 141 is fixed to the endless belt 144.
[0154]
A drive gear 146 is attached to a support shaft (not shown) of the first pulley 142. The drive gear 146 is a pinion 148 attached to an output shaft 147a of a forward / reversely-rotatable stepping motor 147 attached to one side plate 35b. Are engaged.
According to the above-described configuration, the paper receiving plate 141 receives one end of the surface-printed paper PA indicated by a solid line in FIG. 16 due to the forward / reverse operation of the stepping motor 147, and the upper surface thereof indicated by a two-dot chain line in FIG. The other end of the upper surface printed paper PA reciprocates to selectively occupy the second position where it contacts the endless belt 38. A home position sensor 149 is provided near the second pulley 143 to detect when the sheet receiving plate 141 occupies the first position, which is the home position.
[0155]
According to the third embodiment, the reciprocating path of the sheet receiving plate 141 is inclined so as to be substantially the same as the path of the surface-printed sheet PA falling to the auxiliary tray 8. By transporting the finished surface-printed paper PA while receiving it with the paper receiving plate 141 in a state close to its movement path, the surface-printed paper PA can be smoothly received on the upper surface of the paper receiving plate 141, and the paper condition It is possible to suppress the occurrence of transport jam even if the image conditions, environmental conditions, and the like vary.
[0156]
【The invention's effect】
According to the present invention, it is possible to perform one-sided printing in the same manner as a normal stencil printing apparatus without wasteful use of the master, and transfer both the front side image and the back side image printed on the paper from the plate cylinder by a press roller. A good double-sided printed material can be obtained by forming with the ink to be formed, and the installation space can be increased by configuring the apparatus without significantly increasing the size as compared with a normal stencil printing apparatus for single-sided printing. Can be suppressed. Further, the end of the second surface-printed sheet is prevented by preventing the first surface-printed sheet from coming into contact with the second surface-printed sheet during continuous printing. In addition, it is possible to prevent the occurrence of rubbing and dirt on one side of the back surface portion and the first surface-printed sheet, and it is possible to satisfactorily transport the second surface-printed sheet toward the auxiliary tray.
[Brief description of the drawings]
FIG. 1 is a schematic front view of a duplex printing apparatus to which an embodiment of the present invention can be applied.
FIG. 2 is a schematic front view illustrating a press roller contact / separation mechanism used in an embodiment of the present invention and a press roller separated from an outer peripheral surface of a plate cylinder.
FIG. 3 is a schematic plan view illustrating a sheet re-feeding and conveying unit used in one embodiment of the present invention and a sheet receiving plate used in the first embodiment.
FIG. 4 is a schematic side view illustrating a press roller contact / separation mechanism used in an embodiment of the present invention.
FIG. 5 is a schematic front view illustrating a press roller contact / separation mechanism used in an embodiment of the present invention and a press roller in contact with an outer peripheral surface of a plate cylinder.
FIG. 6 is a schematic diagram illustrating a divided master making master used in one embodiment of the present invention.
FIG. 7 is a schematic diagram illustrating a prepressed master used in one embodiment of the present invention.
FIG. 8 is a schematic diagram showing an operation panel used in one embodiment of the present invention.
FIG. 9 is a block diagram of control means used in one embodiment of the present invention.
FIG. 10 is a schematic front view of a main part of a printing unit for explaining a problem during continuous printing of the double-sided printing apparatus used in one embodiment of the present invention.
FIG. 11 is a schematic front view of a main part of a printing unit for describing a problem at the time of continuous printing of the duplex printing apparatus used in the embodiment of the present invention.
FIG. 12 is a schematic front view of a main part of a printing unit for explaining a continuous printing operation in the first embodiment of the present invention.
FIG. 13 is a schematic front view of a main part of a printing unit for explaining a continuous printing operation in the first embodiment of the present invention.
FIG. 14 is a schematic plan view illustrating a sheet receiving plate used in a second embodiment of the present invention.
FIG. 15 is a schematic front view of a main part of a printing unit for explaining a sheet receiving plate used in a second embodiment of the present invention.
FIG. 16 is a schematic front view of a main part of a printing unit for explaining a paper receiving plate used in a second embodiment of the present invention.
FIG. 17 is a schematic diagram illustrating a driving mechanism of a sheet receiving plate used in a third embodiment of the present invention.
[Explanation of symbols]
1 Double-sided printing device
2 Printing Department
4 Paper feed unit
6 Paper output unit
8 Auxiliary tray
8a End fence
8c Front side printed paper detection member (sensor)
9 Refeeding means
10 Switching member
12 plate cylinder
13 Press roller
24 Refeed positioning member
25 Re-feeding conveyance unit
38 Paper transport member (endless belt)
40,140,141 Paper receiving plate
40e fitting part (notch part)
65 Master with divided prepress
65A First plate making image
65B Second plate making image
140e, 141e Side fence
140g, 141f end fence
P paper
PA Surface-printed paper
PB Printed paper

Claims (8)

A plate cylinder for winding a divided plate-making master, on which two first plate-making images and second plate-making images are arranged in the length direction, on an outer peripheral surface, and a press roller provided so as to be able to freely contact and separate from the plate cylinder. A printing unit, a paper feeding unit for feeding paper toward the printing unit, a paper discharging unit for discharging printed paper printed on the printing unit out of the machine, and a surface of the printing unit on the printing unit. A sheet re-feeding means for temporarily re-feeding the front-side printed paper having the printed image formed thereon, and re-feeding the front-side printed paper stored on the auxiliary tray toward the printing unit; A switching member for guiding the sheet that has passed through the printing unit to either the auxiliary tray or the discharge unit,
At the time of double-sided printing, the first sheet is fed from the paper feeding unit to the printing unit, and one of the first plate-making image and the second plate-making image is printed on the surface thereof, and the first printed sheet is printed. After the sheet is guided to the auxiliary tray by the switching member, a second sheet is fed from the sheet feeding unit to the printing unit, and either one of the first plate-making image or the second plate-making image is provided on the surface thereof. At the same time as printing, the first sheet is re-supplied to the printing unit by the re-feeding unit, and either the first plate-making image or the second plate-making image is printed on the back surface thereof, and one sheet is printed by the switching member. A double-sided printing apparatus for guiding an eye sheet to the discharge unit and a second sheet to the auxiliary tray,
The sheet re-feeding means includes a sheet conveying member having an upper surface exposed on an upper surface of the auxiliary tray that conveys the surface-printed paper stored on the auxiliary tray toward the press roller. A unit and a paper receiving plate provided above the upper surface of the paper transporting member with a slight gap therebetween and receiving one end of the front side printed paper guided toward the auxiliary tray by the switching member, The double-sided printing apparatus according to claim 1, wherein the sheet receiving plate is reciprocally movable above the auxiliary tray in the same direction as the direction in which the front-side printed sheet is transported by the re-feeding transport unit. 2. The double-sided printing apparatus according to claim 1, wherein the sheet receiving plate is closest to the press roller during one rotation of the plate cylinder, and is farthest from the first position for receiving one end of the front side printed sheet and the press roller. The other end of the surface-printed sheet on the upper surface thereof makes one reciprocation between a second position where it contacts the paper transport member, and one end of the surface-printed sheet guided by the switching member is the auxiliary tray. A double-sided printing apparatus characterized in that it occupies a first position when it falls down. 3. The double-sided printing apparatus according to claim 2, wherein the re-feeding unit temporarily stops the front-printed sheet transported by the re-feed transport unit at a predetermined position before the press roller. When the paper receiving plate occupies the second position, the other end of the front-side printed sheet abuts on the re-feeding positioning member and the front-side printed sheet is re-positioned by the re-feeding positioning member. A two-sided printing apparatus, wherein a temporary stop is performed and one end of the front side printed paper falls from the paper receiving plate. 4. The double-sided printing apparatus according to claim 3, further comprising: a front-side printed sheet detecting member that detects that the other end of the front-side printed sheet is close to the re-feeding positioning member. The double-sided printing apparatus according to claim 2, wherein after the detection of the other end, the sheet receiving plate is moved from a second position to a first position. 5. The double-sided printing apparatus according to claim 1, wherein the auxiliary tray is guided by the switching member, and one end of the front-printed sheet dropped on the sheet receiving plate is in contact with the auxiliary tray. A double-sided printing apparatus having an end fence, wherein the paper receiving plate has a fitting portion that fits into the end fence when occupying a second position. 5. The double-sided printing apparatus according to claim 1, wherein the sheet receiving plate is guided by the switching member, and one end of the front-side printed sheet dropped on the upper surface thereof is in contact with the end fence. 6. A double-sided printing apparatus comprising: The double-sided printing apparatus according to any one of claims 1 to 6, wherein the sheet receiving plate includes a pair of side fences for aligning both side edges of the surface-printed sheet. Double-sided printing device. 8. The double-sided printing apparatus according to claim 1, wherein a reciprocating path of the sheet receiving plate is substantially the same as a path of dropping the front side printed sheet to the auxiliary tray. A double-sided printing apparatus characterized by being provided at an inclination.

Images