The present invention relates to a sheet processing apparatus including a sheet reversing mechanism which performs a process such as printing on the obverse surface of a sheet, and subsequently performs a process such as printing on the reverse surface of the sheet.
Conventionally, a sheet-fed offset rotary printing press including a sheet reversing mechanism which prints on the obverse surface of a sheet, and subsequently prints on the reverse surface of the sheet upon turning the sheet has been proposed. The conventional sheet-fed offset rotary printing press equipped with a reversing mechanism includes a first printing unit which prints on the obverse surface of a sheet, a second printing unit which is arranged adjacent to the first printing unit and prints on the reverse surface of the sheet, and a sheet reversing unit which turns the sheet in the interval between the first and second printing units. With such an arrangement, one printing press is capable of single- and double-sided printing.
However, the above-mentioned conventional sheet-fed offset rotary printing press equipped with a reversing mechanism is independently provided with a first printing unit which prints on the obverse surface of a sheet, and a second printing unit which prints on the reverse surface of the sheet, so the entire printing press occupies a large space and has a large size.
It is an object of the present invention to provide a compact sheet processing apparatus capable of printing on both the obverse and reverse surfaces of a sheet.
In order to achieve the above-mentioned object, according to the present invention, there is provided a sheet processing apparatus comprising a sheet supply device which supplies sheets one by one, a first cylinder which comprises at least one gripper device that grips one edge of the sheet supplied from the sheet supply device, and grips and conveys the sheet by the gripper device, a processing device which processes the sheet conveyed by the first cylinder, a sheet discharge device which discharges the sheet processed by the processing device, and conveyance devices which include a plurality of gripper devices including at least one reversing gripper device that grips and holds the other edge of the sheet, convey the sheet that has undergone a single-sided process and is received from the first cylinder while sequentially transferring the sheet by a gripping change by the plurality of gripper devices, reverse the sheet in the process of conveyance, and supply the sheet onto the first cylinder, the conveyance devices comprising a second cylinder which grips and conveys one edge of the sheet by one gripper device of the plurality of gripper devices, and a reversing swing arm shaft pregripper which is supported to be swingable between the first cylinder and the second cylinder, receives by the reversing gripper device the other edge of the sheet conveyed by the second cylinder, and transfers the received other edge of the sheet to the gripper device of the first cylinder by a gripping change.
According to the present invention, since a sheet conveyance operation and reversal operation are performed by a gripping change only by a gripper device, it is possible to obtain high obverse/reverse registration accuracy. Also, since obverse printing and reverse printing are performed using the same printing cylinder, it is possible to attain a compact digital printing apparatus which performs high-quality double-sided printing on a sheet without increasing the size of the entire apparatus.
A sheet processing apparatus according to the present invention will be described in detail below with reference to the accompanying drawings.
A digital printing apparatus 1 (sheet processing apparatus) according to this embodiment includes a sheet feed device 2 (sheet supply device), a digital printing unit 3 (processing unit), and a sheet delivery device 4 (sheet discharge device), as shown in
The sheet feed device 2 includes a pile board 21 on which a plurality of sheets S1 are stacked, and a sucker device 23 which conveys the top sheet S1 on the pile board 21 onto a feeder board FB. The sucker device 23 includes a pair of suction ports 23a and 23b, which are connected to a negative pressure source 25 via a continuous supply valve 26 and an intermittent supply valve 27.
The continuous supply valve 26 and intermittent supply valve 27 enable/disable, at different timings, the suction operation of the suction ports 23a and 23b using a negative pressure from the negative pressure source 25.
A swing arm shaft pregripper 31f is disposed on the distal end side of the feeder board FB in the sheet conveyance direction. The swing arm shaft pregripper 31f is swingably supported on a frame 3a of the digital printing unit 3, and includes a gripper device (not shown) which grips and holds the leading edge (front edge) of the sheet S1 as its one edge. A feed-side transfer cylinder 32 is opposed to the swing arm shaft pregripper 31f, and rotatably supported on the frame 3a. A gripper device 32a which holds the leading edge of the sheet S1, transferred by a gripper device of the swing arm shaft pregripper 31f, in a gripped state is provided on the feed-side transfer cylinder 32. The swing arm shaft pregripper 31f and feed-side transfer cylinder 32 constitute an upstream sheet conveyance device. Note that in the following description, the gripper device is formed by a plurality of grippers aligned in the cylinder axis direction with predetermined gaps between them.
A printing cylinder 33 (first cylinder) with a diameter three times that of the feed-side transfer cylinder 32 is opposed to the feed-side transfer cylinder 32 on the downstream side of the swing arm shaft pregripper 31f in the sheet conveyance direction to be in contact with the feed-side transfer cylinder 32, and is rotatably supported on the frame 3a. The printing cylinder 33 includes printing cylinder gripper devices 33a, 33b, and 33c which hold the leading edge of the sheet 51 upon receiving it from the gripper device 32a of the feed-side transfer cylinder 32, and support surfaces 33d, 33e, and 33f which are provided in correspondence with the printing cylinder gripper devices 33a, 33b, and 33c, and support the sheet 51. The printing cylinder 33 is implemented by a triple-diameter cylinder provided with three pairs of printing cylinder gripper devices 33a, 33b, and 33c and support surfaces 33d, 33e, and 33f. The printing cylinder gripper devices 33a, 33b, and 33c are provided at positions 120° out of phase with each other in the circumferential direction.
An inkjet nozzle portion 34 is opposed to the circumferential surface of the printing cylinder 33 on the downstream side of the contact portion of the printing cylinder 33 with the feed-side transfer cylinder 32 in the sheet conveyance direction.
The inkjet nozzle portion 34 includes a plurality of ink heads 34a to 34d (to be referred to as ink heads hereinafter) which are juxtaposed in the sheet conveyance direction along the circumferential surface of the printing cylinder 33, and store inks of different colors. Each of the ink heads 34a to 34d is oriented in a direction perpendicular to the circumferential surface of the printing cylinder 33. The ink heads 34a to 34d are arranged in proximity to the printing cylinder 33 to have small gaps with the sheet S1 having its leading edge sucked by the entire support surfaces 33d, 33e, and 33f. The printing cylinder 33 and inkjet nozzle portion 34 constitute a sheet printing device.
An ink drying lamp 35 is opposed to the printing cylinder 33. The ink drying lamp 35 serves as a drying device which is opposed to the printing cylinder 33 on the downstream side of a printing region 33K, printed by the inkjet nozzle portion 34 of the printing cylinder 33, in the sheet conveyance direction, and irradiates the sheet S1 with light such as infrared or ultraviolet rays to dry ink printed on the sheet S1. Note that drying includes applying thermal energy to the ink to evaporate the moisture of the ink, and curing the ink.
The printing cylinder 33 is arranged on the downstream side of the inkjet nozzle portion 34 in the sheet conveyance direction to be in contact with a delivery-side transfer cylinder 36 rotatably supported on the frame 3a. The delivery-side transfer cylinder 36 has a gripper device 36a which holds the leading edge of the sheet S1, conveyed by the printing cylinder 33, upon receiving it from the printing cylinder gripper devices 33a, 33b, and 33c.
Another delivery-side transfer cylinder 37 is arranged on the downstream side of the contact portion of the delivery-side transfer cylinder 36 with the printing cylinder 33 in the sheet conveyance direction to be in contact with the delivery-side transfer cylinder 36. The delivery-side transfer cylinder 37 is rotatably supported on the frame 3a. The delivery-side transfer cylinder 37 has a gripper device 37a (upstream gripper device) which receives and holds the leading edge of the sheet S1 conveyed by the delivery-side transfer cylinder 36.
A delivery cylinder 38 is arranged on the downstream side of the contact portion of the delivery-side transfer cylinder 37 with the delivery-side transfer cylinder 36 in the sheet conveyance direction to be in contact with the delivery-side transfer cylinder 37. The delivery cylinder 38 is rotatably supported on the frame 3a. The delivery cylinder 38 has a gripper device 38a (downstream gripper device) which receives and holds the leading edge of the sheet S1 conveyed by the delivery-side transfer cylinder 37.
A belt conveyor-shaped delivery belt 40 which conveys the sheet S1 is disposed below the delivery cylinder 38. A pile board 41 which stacks sheets S1 having undergone a digital printing process by the digital printing unit 3 is provided on the leading edge side of the delivery belt 40 in the sheet conveyance direction. The delivery cylinder 38, delivery belt 40, and pile board 41 constitute the sheet delivery device 4. Also, the path of the sheet S1 conveyed by the delivery cylinder 38 and delivery belt 40 constitutes a sheet discharge path.
A pre-reversal double-diameter cylinder 39 (second cylinder) is arranged on the downstream side of the contact portion of the delivery-side transfer cylinder 37 with the delivery cylinder 38 in the sheet conveyance direction. The pre-reversal double-diameter cylinder 39 serves as a pre-reversal transport cylinder and is rotatably supported on the frame 3a. The pre-reversal double-diameter cylinder 39 is implemented by a double-diameter cylinder with a diameter twice that of the delivery-side transfer cylinder 37, and receives and holds the leading edge of the sheet S1 conveyed by the delivery-side transfer cylinder 37.
A reversing swing arm shaft pregripper 31b having a reversing gripper device 31bt which receives and holds the trailing edge (rear edge) of the sheet S1 as its other edge is opposed to the pre-reversal double-diameter cylinder 39 on the downstream side of the contact portion of the pre-reversal double-diameter cylinder 39 with the delivery-side transfer cylinder 37 in the sheet conveyance direction, as shown in
Note that the delivery-side transfer cylinders 36 and 37, pre-reversal double-diameter cylinder 39, and reversing swing arm shaft pregripper 31b constitute a sheet conveyance device 301 which conveys the sheet S1. The reversing gripper device and reversing swing arm shaft pregripper 31b constitute a sheet reversing portion which turns the sheet S1. The path of the sheet S1 conveyed by the delivery-side transfer cylinders 36 and 37, pre-reversal double-diameter cylinder 39, and reversing swing arm shaft pregripper 31b constitutes a sheet reversal path.
The gripper device 37a of the delivery-side transfer cylinder 37 is driven by a conveyance path switching cam mechanism and first switching device (both will be described later) to selectively transfer by a gripping change the sheet S1 between the gripper device 38a of the delivery cylinder 38 and a gripper device 39a of the pre-reversal double-diameter cylinder 39. Also, the gripper device 38a of the delivery cylinder 38 is driven by a conveyance path switching cam mechanism and second switching device (both will be described later) to selectively receive the leading edge of the sheet S1 conveyed by the delivery-side transfer cylinder 37. The gripper devices 37a and 38a constitute a conveyance path switching device 82 which switches the conveyance destination of the sheet S1 to the sheet delivery device 4 or reversing swing arm shaft pregripper 31b, that is, switches the conveyance destination of the sheet S1 to the sheet discharge path or the sheet reversal path.
A gear 71 which meshes with a gear 37d of a delivery-side transfer cylinder 37 is fixed to a shaft 70 rotatably supported on the frame 3a, as shown in
A cam member 37b is provided on the frame 3a opposed to one end face of the delivery-side transfer cylinder 37, as shown in
The third cam 37b3 has a proximal end pivotally supported on the frame 3a by a pivot shaft 37b4, and a free end to which an arm portion 37c4 is connected via a pin 37c3. An arm portion 37c5 is connected to the arm portion 37c4 via a pin 37c2, and a shaft 37c1 is fixed to the arm portion 37c5 to be pivotally supported on the frame 3a. The arm portions 37c4 and 37c5 and pin 37c2 constitute a link 37c.
A lever 50 is fixed to the shaft 37c1, as shown in
The frame 3a is equipped with an air cylinder 56 serving as an actuator through a bracket 55, and the distal end of a rod 56a of the air cylinder 56 is opposed to the pin 53 of the lever 50. A stopper 57 with its distal end which abuts against the end face of the lever 50 on the side of the shaft 70 is fixed to the frame 3a on the opposite side of the pin 53 with respect to the air cylinder 56.
A cam follower 37a2 and the gripper shaft of a gripper 37a1 which constitutes the gripper device 37a of the delivery-side transfer cylinder 37 are connected to each other via a lever 37a3, as shown in
A cam member 38b is provided on the frame 3a opposed to one end face of the delivery cylinder 38, as shown in
An arm portion 38c4 is connected to the second cam 38b2 via a pin 38c3, while an arm portion 38c5 is connected to the arm portion 38c4 via a pin 38c2. The arm portion 38c5 is fixed to a shaft 38c1 pivotally supported on the frame 3a. The arm portions 38c4 and 38c5 and pin 38c2 constitute a link 38c.
Levers 80 and 81 are fixed to the shaft 38c1 to be integrally swingable, as shown in
An air cylinder 87 serving as an actuator is attached to the frame 3a through a bracket 86. The distal end of a rod 87a of the air cylinder 87 is opposed to the pin 84 of the lever 81. A stopper 88 with its distal end which abuts against one end face of the lever 81 is fixed to the frame 3a on the opposite side of the pin 84 with respect to the air cylinder 87.
A cam follower 38a2 and the gripper shaft of a gripper 38a1 which constitutes the gripper device 38a of the delivery cylinder 38 are connected to each other via a lever 38a3, as shown in
A feed-side sheet gripping change mechanism which transfers the sheet S1 by a gripping change between the gripper device 32a of the feed-side transfer cylinder 32, and the gripper devices 33a, 33b, and 33c of the printing cylinder 33 will be described.
A cam member 32b is provided on the frame 3a opposed to one end face of the feed-side transfer cylinder 32, as shown in
An arm portion 32c4 is connected to the second cam 32b2 via a pin 32c3, while an arm portion 32c5 is connected to the arm portion 32c4 via a pin 32c2. The arm portion 32c5 is fixed to a shaft 32c1 pivotally supported on the frame 3a. A feed-side first switching device 106 (
A cam follower 32a2 and the gripper shaft of a gripper 32a1 which constitutes the gripper device 32a of the feed-side transfer cylinder 32 are connected to each other via a lever 32a3. The cam follower 32a2 connected to the lever 32a3 is in contact with the circumferential surfaces of a first cam 32b1 and a second cam 38b2. A biasing means of a torsion bar (not shown) applies a biasing force to the cam follower 32a2 in the direction to press it against the circumferential surfaces of the first cam 32b1 and second cam 32b2.
A first cam 33k1 and a second cam 33k2 are provided on the frame 3a opposed to one end face of the printing cylinder 33. The first cam 33k1 is fixed to the frame 3a near the position at which it is opposed to the reversing swing arm shaft pregripper 31b, and the second cam 33k2 is movably provided on the frame 3a near the contact portion with the feed-side transfer cylinder 32.
The proximal end of the second cam 33k2 is pivotally supported on the frame 3a by a swing shaft 33k3. The free end of the second cam 33k2 is connected to an arm portion 33n4 via a pin 33n3.
An arm portion 33n5 is connected to the arm portion 33n4 via a pin 33n2, and a shaft 33n1 is fixed to the arm portion 33n5 to be pivotally supported on the frame 3a. A feed-side second switching device 107 (
A cam follower 33a2 and the gripper shaft of a gripper 33a1 which constitutes the gripper device 33a of the printing cylinder 33 are connected to each other via a lever 33a3. The cam follower 33a2 connected to the lever 33a3 is in contact with the circumferential surfaces of a cam member 33k, the first cam 33k1, and the second cam 33k2. A biasing means of a torsion bar (not shown) applies a biasing force to the cam follower 33a2 in the direction to press it against the circumferential surfaces of the first cam 33k1 and second cam 33k2.
A fixed cam 39b is fixed to the frame 3a, opposed to one end face of the pre-reversal double-diameter cylinder 39, near the position at which it is opposed to the delivery-side transfer cylinder 37, and a movable cam 39d is movably provided on the frame 3a, as shown in
A semicircular disk-shaped segment gear 39c to which the movable cam 39d is fixed is supported by the pre-reversal double-diameter cylinder 39 to be pivotal about the shaft of the pre-reversal double-diameter cylinder 39. A pinion 39cp connected to the sheet size adjusting motor 108 (
A cam follower 39a2 and the gripper shaft of a gripper 39a1 which constitutes the gripper device 39a of the pre-reversal double-diameter cylinder 39 are connected to each other via a lever 39a3. The cam follower 39a2 is in contact with the circumferential surfaces of the fixed cam 39b and movable cam 39d. A biasing means of a torsion bar (not shown) applies a biasing force to the cam follower 39a2 in the direction to press it against the circumferential surfaces of the fixed cam 39b and movable cam 39d.
The configuration of the control system for the digital printing apparatus 1 will be described next. A control device 100 implemented by a CPU (Central Processing Unit) is connected to a printing mode selection switch 101 which selects a single-sided printing mode or a double-sided printing mode, a sheet size input device 102 which receives a sheet size input by the operator, a rotary encoder 103 serving as a phase detection device, a solenoid valve 104 which switches the operation of the air cylinder 56 (
The printing operation of the digital printing apparatus 1 configured as mentioned above will be described separately for the case wherein the single-sided printing mode is selected and that wherein the double-sided printing mode is selected.
Prior to the operation of the digital printing apparatus 1, first, the operator operates the printing mode selection switch 101 (
As the continuous supply valve 26 operates, suction from the suction ports 23a and 23b is performed by a negative pressure from the negative pressure source 25 at each timing (first period) at which the same number of sheets S1 as the number of printing cylinder gripper devices 33a, 33b, and 33c of the printing cylinder 33 are supplied during 360° rotation of the printing cylinder 33, that is, at each timing (period) at which the printing cylinder gripper devices 33a, 33b, and 33c in the printing cylinder 33, and the gripper device 32a of the feed-side transfer cylinder 32 are opposed to each other. In this manner, supply of the sheet S1 so that all the gripper devices 33a, 33b, and 33c of the printing cylinder 33 grip the sheet S1 will be referred to as continuous sheet feed hereinafter. Upon actuation of the continuous supply valve 26, the sucker device 23 supplies the sheet S1 onto the feeder board FB at the first period.
The leading edge of the sheet S1 conveyed by the feeder board FB is held by the gripper device of the swing arm shaft pregripper 31f, and the sheet S1 is conveyed onto the feed-side transfer cylinder 32 upon a swing of the swing arm shaft pregripper 31f. The leading edge of the sheet S1 is transferred by a gripping change to the gripper device 32a of the feed-side transfer cylinder 32.
In selecting the single-sided printing mode, the control device 100 controls the first switching device 106 to set the second cam 32b2 of the feed-side transfer cylinder 32 at a gripping change position (a solid line in
When the sheet S1 passes through the contact portion between the feed-side transfer cylinder 32 and the printing cylinder 33, the cam follower 33a2 of the gripper device 33a of the printing cylinder 33 passes along the cam surface of the second cam 33k2, so the gripper 33a1 opens/closes through the lever 33a3, as shown in
The cam follower 32a2 of the feed-side transfer cylinder 32 passes through the cam surface of the second cam 32b2 while engaging with it, so the gripper 32a1 opens through the lever 32a3 to cancel holding of the sheet S1. With this operation, the sheet S1 is transferred by a gripping change from the gripper device 32a of the feed-side transfer cylinder 32 to the gripper device 33a of the printing cylinder 33. The gripper 32a1 closes after the cam follower 32a2 passes through the cam surface of the second cam 32b2.
The sheet S1 held by the gripper device 33a of the printing cylinder 33 passes between the printing cylinder 33 and the inkjet nozzle heads 34a to 34d of the inkjet nozzle portion 34 while being conveyed with rotation of the printing cylinder 33. At this time, a digital printing process is performed on the obverse surface (one surface) of the sheet S1 as minute droplets of ink discharged from the inkjet nozzle heads 34a to 34d are adhered onto this surface.
When the sheet S1 having undergone a digital printing process on its obverse surface passes between the printing cylinder 33 and the ink drying lamp 35, ink adhered on the sheet S1 is dried or cured with light emitted by the ink drying lamp 35, and is conveyed onto the delivery-side transfer cylinder 36. When the sheet S1 passes through the contact portion between the printing cylinder 33 and the delivery-side transfer cylinder 36, the leading edge of the sheet S1 is transferred by a gripping change from the gripper device 33a of the printing cylinder 33 to the gripper device 36a of the delivery-side transfer cylinder 36, as shown in
When the sheet S1 passes through the contact portion between the delivery-side transfer cylinders 36 and 37, the cam follower 37a2 of the gripper device 37a of the delivery-side transfer cylinder 37 passes through the cam surface of the first cam 37b1 of the cam member 37b, so the gripper 37a1 opens/closes through the lever 37a3. With this operation, the leading edge of the sheet S1 held by the gripper device 36a of the delivery-side transfer cylinder 36 is gripped by the gripper 37a1 of the gripper device 37a of the delivery-side transfer cylinder 37. The gripper device 36a of the delivery-side transfer cylinder 36 opens to cancel holding of the sheet S1. With this operation, the sheet S1 is transferred by a gripping change from the gripper device 36a of the delivery-side transfer cylinder 36 to the gripper device 37a of the delivery-side transfer cylinder 37.
In selecting the single-sided printing mode, the control device 100 controls the solenoid valve 104 to extend the rod 56a of the air cylinder 56. As the rod 56a of the air cylinder 56 extends, the distal end of the rod 56a abuts against the pin 53 of the lever 50. As the rod 56a further extends, the lever 50 swings against the biasing force of the spring gear 54 and abuts against the stopper 57. With this operation, the lever 50 is set at a retreat position (a solid line in
As the lever 50 swings to the retreat position, the shaft 37c1 pivots. As the shaft 37c1 pivots, the arm portions 37c4 and 37c5 of the link 37c pivot to set the third cam 37b3 at an actuation position (a solid line in
At the same time, the control device 100 controls the solenoid valve 105 to extend the rod 87a of the air cylinder 87. As the rod 87a extends, the distal end of the rod 87a abuts against the pin 84 of the lever 81. As the rod 87a further extends, the lever 81 swings against the biasing force of the spring gear 85 and abuts against the stopper 88. With this operation, the lever 81 is set at an actuation position (a solid line in
As the lever 80 swings to the retreat position, the shaft 38c1 pivots. As the shaft 38c1 pivots, the arm portions 38c4 and 38c5 of the link 38c pivot to set the second cam 38b2 at an actuation position (a solid line in
When the gripper device 37a of the delivery-side transfer cylinder 37 which holds the leading edge of the sheet S1 reaches the contact portion with the delivery cylinder 38, the cam follower 38a2 of the gripper device 38a of the delivery cylinder 38 passes through the cam surface of the second cam 38b2 to open/close the gripper 38a1. With this operation, the leading edge of the sheet S1 held by the gripper device 37a of the delivery-side transfer cylinder 37 is gripped by the gripper 38a1 of the gripper device 38a of the delivery cylinder 38. At this time, the leading edge of the sheet S1 is held by both the gripper device 37a of the delivery-side transfer cylinder 37, and the gripper device 38a of the delivery cylinder 38.
When the cam follower 37a2 of the delivery-side transfer cylinder 37 passes along the cam surface of the third cam 37b3 set at a position indicated by a solid line, the gripper 37a1 opens through the lever 37a3 to cancel holding of the sheet S1 by the gripper 37a1. When the cam follower 37a2 then passes through the cam surface of the third cam 37b3, the gripper 37a1 closes without gripping the sheet S1. With this operation, the sheet S1 is transferred by a gripping change from the gripper device 37a of the delivery-side transfer cylinder 37 to the gripper device 38a of the delivery cylinder 38.
The delivery cylinder 38 rotates while holding the leading edge of the sheet S1 by the gripper device 38a. When the cam follower 38a2 of the delivery cylinder 38 passes along the cam surface of the first cam 38b1, the gripper 38a1 opens through the lever 38a3 to cancel holding of the sheet S1, and the sheet S1 is mounted on the delivery belt 40. When the cam follower 38a2 then passes through the cam surface of the first cam 38b1, the gripper 38a1 closes without gripping the sheet S1. With this operation, the sheet S1 is conveyed from the delivery cylinder 38 onto the delivery belt 40.
The sheet S1 mounted on the delivery belt 40 is conveyed as it travels, and the sheet S1 having undergone a digital printing process only on its one surface (obverse surface) is discharged onto the pile board 41 of the sheet delivery device 4.
The double-sided printing mode is selected by operating the printing mode selection switch 101 by the operator. Also, the size of the sheet S1 is input to the sheet size input device 102 by the operator. The control device 100 actuates the continuous supply valve 26 based on the double-sided printing mode selected by the printing mode selection switch 101. With this operation, the suction ports 23a and 23b suck and supply the sheets S1 on the pile board 21 onto the feeder board FB one by one.
As the intermittent supply valve 27 operates, suction from the suction ports 23a and 23b by a negative pressure from the negative pressure source 25, and the stop of suction are alternately repeated at the alternate sheet supply timing (second period) for the continuous supply timing, that is, the timing at which the gripper devices 33a, 33b, and 33c in the printing cylinder 33, and the gripper device 32a of the feed-side transfer cylinder 32 are opposed to each other. The second period of intermittent supply becomes a period twice the first period of continuous supply. In this manner, supply of the sheet S1 so that the gripper devices 33a, 33b, and 33c of the printing cylinder 33 alternately grip the sheet S1 will be referred to as intermittent sheet feed hereinafter. As the intermittent supply valve 27 is actuated, the sucker device 23 supplies the sheet S1 onto the feeder board FB at the second period.
The sheet S1 conveyed by the feeder board FB is transferred onto the feed-side transfer cylinder 32 through the swing arm shaft pregripper 31f, as in the selection of the single-sided printing mode. Note that the sheet S1 is supplied at the second period, so the feed-side transfer cylinder 32 is gripped and conveyed every other 360° rotation operation.
In selecting the double-sided printing mode, the control device 100 controls the first switching device 106 to alternately set the second cam 32b2 of the feed-side transfer cylinder 32 at a gripping change position (a solid line in
With this operation, the second cams 32b2 and 33k2 of the feed-side transfer cylinder 32 and printing cylinder 33 are set at the timing (second period) at which the gripper device 32a of the feed-side transfer cylinder 32 grips the sheet S1. On the other hand, the second cams 32b2 and 33k2 of the feed-side transfer cylinder 32 and printing cylinder 33 are set at retreat positions at the timing at which the gripper device 32a does not grip the sheet 51. Note that the retreat position of the second cam 32b2 of the gripper device 32a of the feed-side transfer cylinder 32 is the position through which the cam follower 32a2 of the gripper device 32a of the feed-side transfer cylinder 32 passes through the second cam 32b2 while engaging with it, before the transfer timing at which the gripper 32a1 of the gripper device 32a of the feed-side transfer cylinder 32 is opposed to the gripper 33a1 of the gripper device 33a of the printing cylinder 33. The retreat position of the second cam 33k2 of the printing cylinder 33 is the position through which the cam follower 33a2 of the gripper device 33a of the printing cylinder 33 passes through the second cam 33k2 in a non-contact state.
When the gripper device 32a of the feed-side transfer cylinder 32 grips the sheet S1, the cam followers 32a2 and 33a2 of the feed-side transfer cylinder 32 and printing cylinder 33 pass through the cam surfaces of the second cams 32b2 and 33k2 set at griping change positions past the cam followers 32a2 and 33a2 to open/close the grippers 32a1 and 33a1 of the two cylinders to transfer the sheet S1 by a gripping change from the feed-side transfer cylinder 32 onto the printing cylinder 33, as in the single-sided printing mode.
On the other hand, when the gripper device 32a of the feed-side transfer cylinder 32 grips no sheet S1, the cam follower 32a2 of the gripper device 32a engages with the second cam 32b2 set at a retreat position to open the gripper 32a1 at a timing before the transfer timing. With this operation, the gripper 32a1 is opposed to the gripper 33a1 of the printing cylinder 33 and passes in an open state. Also, since the cam follower 33a2 of the gripper device 33a of the printing cylinder 33 is not in contact with the second cam 33k2, the gripper 33a1 is opposed to the gripper 33a1 of the printing cylinder 33 and passes in a closed state. That is, the gripper 32a1 of the gripper device 32a of the feed-side transfer cylinder 32, and the gripper 33a1 of the gripper device 33a of the printing cylinder 33 pass through the contact portion between the two cylinders in open and closed states, respectively.
When the sheet S1 held by the gripper device 33a of the printing cylinder 33 passes between the printing cylinder 33 and the inkjet nozzle heads 34a to 34d of the inkjet nozzle portion 34, a digital printing process is performed on the obverse surface of the sheet S1, as in the selection of the single-sided printing mode. Ink adhered on the obverse surface of the sheet S1 having undergone a digital printing process is dried or cured by the ink drying lamp 35, and the sheet S1 is conveyed onto the delivery-side transfer cylinder 37 through the delivery-side transfer cylinder 36, as shown in
In selecting the double-sided printing mode, the control device 100 controls the solenoid valve 104 to retract the rod 56a of the air cylinder 56. Upon retraction of the rod 56a, the distal end of the rod 56a separates from the pin 53 of the lever 50, and the lever 50 swings against the biasing force of the spring gear 54, so the lever 50 separates from the stopper 57. With this operation, the cam follower 51 is pressed against the cam surfaces 72a and 72b of the first switching cam 72 using the biasing force of the spring gear 54.
At the same time, the control device 100 controls the solenoid valve 105 to retract the rod 87a of the air cylinder 87. Upon retraction of the rod 87a, the distal end of the rod 87a separates from the pin 84 of the lever 81, and the levers 81 and 80 integrally swing using the biasing force of the spring gear 85, so the lever 81 separates from the stopper 88. With this operation, the conveyance path switching device 82 is pressed against the cam surfaces 73a and 73b of the second switching cam 73 using the biasing force of the spring gear 85.
The first switching cam 72 and second switching cam 73 rotate through the gears 37d and 71 and shaft 70 with rotation of the delivery-side transfer cylinder 37. As the first switching cam 72 rotates while the cam follower 51 is pressed against the cam surfaces 72a and 72b of the first switching cam 72, the lever 50 swings along the cam surfaces 72a and 72b of the first switching cam 72 to pivot the shaft 37c1. As the shaft 37c1 pivots, the arm portions 37c4 and 37c5 of the link 37c pivot to alternately set the third cam 37b3 at an actuation position (a position indicated by a solid line in
As the second switching cam 73 rotates while the cam follower 82 is pressed against the cam surfaces 73a and 73b of the second switching cam 73, the levers 80 and 81 swing along the cam surfaces 73a and 73b. With this operation, the shaft 38c1 pivots, and the arm portions 38c4 and 38c5 of the link 38c pivot to alternately set the second cam 38b2 at an actuation position (a solid line in
When the gripper device 37a of the delivery-side transfer cylinder 37 grips the sheet S1 printed on its one surface, the cam follower 51 of the lever 50 is in contact with the cam surface 72b of the first switching cam 72. The cam follower 37a2 of the gripper device 37a of the delivery-side transfer cylinder 37 passes through the third cam 37b3, set at a retreat position, in a non-contact state. With this operation, the gripper 37a1 of the gripper device 37a of the delivery-side transfer cylinder 37 passes through the contact portion between the delivery-side transfer cylinder 37 and the delivery cylinder 38 in a closed state while holding the sheet Sl.
On the other hand, the cam follower 38a2 of the gripper device 38a of the delivery cylinder 38 passes through the cam surface of the second cam 38b2 while engaging with it after the timing of transfer of the sheet S1 by the second cam 38b2 set at a retreat position. With this operation, when the gripper 38a1 of the gripper device 38a of the delivery cylinder 38 is opposed to the gripper 37a1 of the gripper device 37a of the delivery-side transfer cylinder 37, the gripper 38a1 of the gripper device 38a of the delivery cylinder 38 passes in an open state.
With this operation, the sheet S1 with its leading edge held by the gripper 37a1 of the gripper device 37a of the delivery-side transfer cylinder 37 is conveyed onto the pre-reversal double-diameter cylinder 39 with rotation of the delivery-side transfer cylinder 37 without being transferred by a gripping change to the gripper 38a1 of the gripper device 38a of the delivery cylinder 38.
As shown in
When the cam follower 37a2 of the gripper device 37a of the delivery-side transfer cylinder 37 passes through the cam surface of the second cam 37b2 while engaging with it, the gripper 37a1 opens through the lever 37a3 to cancel holding of the sheet S1 by the gripper 37a1. With this operation, the sheet S1 is transferred by a gripping change from the gripper device 37a of the delivery-side transfer cylinder 37 to the gripper device 39a of the pre-reversal double-diameter cylinder 39. When the cam follower 37a2 passes through the cam surface of the second cam 37b2, the gripper 37a1 closes.
As shown in
At the same time, the cam follower 39a2 of the gripper device 39a of the pre-reversal double-diameter cylinder 39 passes through the cam surface of the movable cam 39d while engaging with it (a solid line in
In selecting the double-sided printing mode, the control device 100 controls the sheet size adjusting motor 108 based on the size (the dimension in the sheet conveyance direction) of the sheet S1 input to the sheet size input device 102 prior to the operation of the digital printing apparatus 1. As the sheet size adjusting motor 108 operates, the segment gear 39c moves from a position indicated by a solid line to that indicated by an alternate long and two short dashed line through the pinion 39cp, and the movable cam 39d moves from a position indicated by a solid line to that indicated by an alternate long and two short dashed line with movement of the segment gear 39c. With this operation, when the trailing edge (rear edge) of the sheet S1 is opposed to the reception position of the reversing swing arm shaft pregripper 31b and held by the reversing gripper device 31bt, the movable cam 39d is set at the position at which it engages with the cam follower 39a2 of the gripper device 39a of the pre-reversal double-diameter cylinder 39.
As shown in
Even when the sheet S1 is transferred from the reversing swing arm shaft pregripper 31b onto the printing cylinder 33, every other sheet S1 is intermittently fed by the delivery-side transfer cylinder 37. Therefore, at the timing at which the sheet S1 is transferred from the reversing swing arm shaft pregripper 31b onto the printing cylinder 33, the feed-side transfer cylinder 32 is opposed to the gripper device 33a of the printing cylinder 33 which holds no new sheet S1 conveyed from the feed-side transfer cylinder 32. In this manner, by setting the timing of transfer from the reversing swing arm shaft pregripper 31b, a new sheet S1 conveyed from the feed-side transfer cylinder 32 does not interfere with a turned sheet S1 conveyed from the reversing swing arm shaft pregripper 31b for reverse printing.
As the printing cylinder 33 rotates, the gripper device 33a having received the sheet S1 printed on its one surface is opposed to the gripper device 32a of the feed-side transfer cylinder 32. At this time, the gripper device 32a of the feed-side transfer cylinder 32 holds no sheet S1 by intermittent sheet feed of the sucker device 23. The cam follower 32a2 of the gripper device 32a of the feed-side transfer cylinder 32 passes along the cam surface of the second cam 32b2 while engaging with it, before the transfer timing of the sheet S1 by the second cam 32b2 set at a retreat position. Hence, when the gripper 32a1 of the gripper device 32a of the feed-side transfer cylinder 32 is opposed to the gripper 33a1 of the gripper device 33a of the printing cylinder 33 which holds the sheet S1, it passes in an open state.
Since the second cam 33k2 of the gripper device 33a of the printing cylinder 33 is set at a retreat position, the cam follower 33a2 of the gripper device 33a passes through the second cam 33k2 without abutting against it. Also, the gripper 33a1 of the gripper device 33a of the printing cylinder 33 is opposed to the gripper 32a1 of the gripper device 32a of the feed-side transfer cylinder 32 and passes in a closed state. With this operation, at the timing at which no sheet S1 is supplied by intermittent sheet feed of the sucker device 23, the gripper devices 33a, 33b, and 33c of the printing cylinder 33 hold the sheet S1 printed on its one surface, and pass through the contact portion with the feed-side transfer cylinder 32.
With this arrangement, the gripper devices 33a, 33b, and 33c of the printing cylinder 33 alternately hold a new sheet S1 from the sucker device 23, and a sheet S1 printed on its one surface from the reversing swing arm shaft pregripper 31b, and convey them to the inkjet nozzle portion 34.
The control device 100 controls the inkjet nozzle heads 34a to 34d of the inkjet nozzle portion 34 to perform reverse printing on a turned sheet S1 printed on its one surface based on the output from the rotary encoder 103, and perform obverse printing on a new sheet S1 from the sucker device 23. With this operation, the inkjet nozzle heads 34a to 34d alternately perform obverse printing and reverse printing corresponding to new and turned sheets S1 alternately held by the printing cylinder 33.
The sheet S1 printed on its reverse surface is discharged from the delivery belt 40 onto the pile board 41 of the sheet delivery device 4 sequentially through the delivery-side transfer cylinders 36 and 37 and delivery cylinder 38, as in the single-sided printing mode.
As described above, according to this embodiment, digital printing processes for the obverse and reverse surfaces of the sheet S1 are performed using the same printing cylinder 33 and the same inkjet nozzle portion 34. This allows a more efficient double-sided printing process on the sheet S1 with space saving, compared to the case wherein a printing cylinder and inkjet nozzle portion for a reverse printing process are provided separately.
Also, according to this embodiment, in sequentially transferring a sheet S1 onto the feed-side transfer cylinder 32, printing cylinder 33, delivery-side transfer cylinders 36 and 37, pre-reversal double-diameter cylinder 39, and reversing swing arm shaft pregripper 31b, the sheet S1 is conveyed while always being kept in a gripped state by the respective gripper devices through the cam surfaces of the corresponding cams. This makes it possible to obtain high registration accuracy and high obverse/reverse registration accuracy of the obverse and reverse surfaces of the sheet S1 in the conveyance direction or widthwise direction of the sheet S1, thus improving the printing quality of the sheet S1.
Moreover, according to this embodiment, an operation of opening/closing the respective gripper devices through the cam surfaces of the corresponding cams in the feed-side transfer cylinder 32, printing cylinder 33, delivery-side transfer cylinder 37, and delivery cylinder 38 is mechanically executed. This allows a reliable gripping change operation of the sheet 51.
Note that in the above-mentioned embodiment, the present invention is applied to a digital printing apparatus 1 serving as a sheet processing apparatus which performs a digital printing process on the sheet S1 by the printing cylinder 33 and inkjet nozzle portion 34. The present invention is not limited to this, and various processes including an offset printing process, inspection process, foil transfer process, and embossing process may be applied to a sheet processing apparatus on the sheet S1.
Also, in the above-mentioned embodiment, the sheet S1 is discharged or turned using the delivery-side transfer cylinders 36 and 37, delivery cylinder 38 or pre-reversal double-diameter cylinder 39, and reversing swing arm shaft pregripper 31b in the subsequent stage of the printing cylinder 33. The present invention is not limited to this, and the pre-reversal double-diameter cylinder 39 may be set in contact with the printing cylinder 33, and the delivery belt 40 may be disposed below the pre-reversal double-diameter cylinder 39 to directly transfer the sheet S1 from the printing cylinder 33 onto the pre-reversal double-diameter cylinder 39, and convey it onto the delivery belt 40. Alternatively, the sheet S1 held by the pre-reversal double-diameter cylinder 39 may be turned by the reversing swing arm shaft pregripper 31b and supplied onto the printing cylinder 33.
Moreover, although the printing cylinder 33 implemented by a triple-diameter cylinder is used as a printing cylinder in the above-mentioned embodiment, the present invention is not limited to this, and a printing cylinder implemented by a double-, quadrupole- or more multiple-diameter cylinder may be used.
Number | Date | Country | Kind |
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098714/2012 | Apr 2012 | JP | national |