The present invention relates to a sheet-fed offset rotary printing press with a convertible press mechanism which turns a sheet over when the sheet is to be gripping-changed from an upstream transport cylinder to a downstream transport cylinder in a sheet convey direction to perform double-sided printing.
In a sheet-fed offset rotary printing press with a convertible press mechanism of this type, a sheet gripped by the grippers of an upstream transport cylinder in the sheet convey direction is not gripping-changed, when the grippers of the upstream transport cylinder oppose a downstream transport cylinder, and passes by the downstream transport cylinder. After that, when the trailing edge of the sheet opposes the downstream transport cylinder, it is gripped by the grippers of the downstream transport cylinder. In this state, the downstream transport cylinder continues rotation, and the grippers of the upstream transport cylinder release the sheet, to turn the sheet over. At this time, if the sheet stays in tight contact with the surface of the upstream transport cylinder and does not separate from it, the sheet may be damaged, or a gripping-change error occurs. In order to prevent this, air is blown to the upstream transport cylinder so that the sheet is separated from the surface of the upstream transport cylinder.
A conventional sheet-fed offset rotary printing press with a convertible press mechanism comprises an air blowing means fixed inside a notch in a convertible cylinder, as shown in U.S. Pat. No. 5,413,040. When a sheet is to be gripping-changed from an impression cylinder to the convertible cylinder, air is blown to the gap between the outer surface of the impression cylinder and the sheet to be separated from separate the sheet which is in tight contact with the outer surface of the impression cylinder.
In the conventional sheet-fed offset rotary printing press with the convertible press mechanism described above, the air blowing means is fixed in the notch of the convertible cylinder. As the convertible cylinder rotates, the air blowing means also rotates to change the air blowing direction. This shortens the blowing time of the air from the air blowing means toward the sheet, so the quantity of air blown to the sheet becomes insufficient. The sheet thus stays in tight contact with the impression cylinder and cannot be reliably separated from the outer surface of the impression cylinder. The air blowing means is integrally rotated with the convertible cylinder. Thus, a hose or the like to supply air from an air source to the air blowing means must be provided in the convertible cylinder. This complicates the structure.
It is an object of the present invention to provide a sheet-fed offset rotary printing press with a convertible press mechanism which can reliably separate a sheet, which is to be gripping-changed from an upstream transport cylinder to a downstream transport cylinder, from the surface of the upstream transport cylinder.
In order to achieve the above object, according to the present invention, there is provided a sheet-fed offset rotary printing press with a convertible press mechanism, comprising an upstream transport cylinder which conveys a sheet by holding a leading edge thereof, a downstream transport cylinder which is arranged downstream of the upstream transport cylinder in a sheet convey direction and holds a trailing edge of the sheet being conveyed by the upstream transport cylinder, a convertible press mechanism which causes the downstream transport cylinder to hold the sheet in a turned state when the sheet is to be transferred from the upstream transport cylinder to the downstream transport cylinder, and a pair of air blowing means, arranged at different heights on outer sides of two ends in a widthwise direction of the sheet, for blowing air toward a center in the widthwise direction of the sheet which is turned over by the convertible press mechanism, so as to separate the sheet from the upstream transport cylinder.
A sheet-fed offset rotary printing press with a convertible press mechanism according to an embodiment of the present invention will be described with reference to FIGS. 1 to 5.
As shown in
A transfer cylinder 12, a chucking cylinder 13 serving as an upstream transport cylinder, and a convertible cylinder 15 serving as a downstream transport cylinder with a convertible press mechanism are interposed between the impression cylinder 7b of the second-color printing unit 3b and the impression cylinder 7c of the third-color printing unit 3c. A delivery cylinder 10 is arranged between the impression cylinder 7d and delivery device 4 to be in contact with the impression cylinder 7d, and supplies a sheet printed by the printing unit 3d to the delivery device 4. A transfer cylinder 11 is arranged between the feed device 2 and printing unit 3a to be in contact with the impression cylinder 7a, and adjusts registration of the surface of a sheet received from a swing device (not shown).
When the convertible press mechanism of the convertible cylinder 15 is set in an inoperative state, the printing press 1 performs single-sided printing of printing patterns of four different colors on the obverse surface of a sheet fed from the feed device 2 to the printing device 3. When the convertible press mechanism of the convertible cylinder 15 is set in an operative state, the printing press 1 performs double-sided printing. Namely, after the printing units 3a and 3b print the patterns of the two different colors on the obverse surface of the sheet, the sheet is turned over by the convertible cylinder 15. Then, the printing units 3c and 3d print patterns of two different colors on the reverse surface of the sheet. The sheet printed by the printing device 3 is delivered to the delivery device 4.
As shown in
Referring to
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When seen from above, the air blowing directions from the blowing ports 26a and 27a are set to be inclined inwardly by a predetermined angle (horizontally) toward the chucking cylinder 13, as shown in
As shown in
In this arrangement, when single-sided printing is to be performed, a valve (not shown) is controlled to supply air to the air pipes 19, 20, and 21, and the convertible press mechanism of the convertible cylinder 15 is set in the inoperative state. In this state, when the grippers 30 of the chucking cylinder 13 reach the opposing point X of the convertible cylinder 15, the paper sheet P with the leading edge gripped by the grippers 30 is gripping-changed to the grippers 32b of the convertible press mechanisms 33a of the convertible cylinder 15. The gripping-changed paper sheet P is conveyed in tight contact with the outer surface of the convertible cylinder 15 by air discharged from the air nozzles 23 and 24. When the grippers 32b reach the opposing point of the impression cylinder 7c, the paper sheet P gripped by the grippers of the impression cylinder 7c is printed in the third color on its obverse surface by the printing unit 3c.
When double-sided printing is to be performed, the valve (not shown) is controlled to supply air to the air pipes 19, 20, and 21 and air nozzles 26 and 27. Subsequently, the upstream cylinder group in the sheet convey direction which includes the chucking cylinder 13 is adjusted in phase in the circumferential direction with respect to the convertible cylinder 15 by an angle corresponding to the vertical length of the paper sheet P. Then, the convertible press mechanism is set in the operative state to start printing operation. The paper sheet P with the leading edge gripped by the grippers 30 of the chucking cylinder 13 is conveyed such that the grippers 30 pass through the opposing point X of the chucking cylinder 13 and convertible cylinder 15 and come into contact with the lower side of the outer surface of the chucking cylinder 13.
When the trailing edge of the paper sheet P chucked by the chuck members 31 reaches the opposing point X of the chucking cylinder 13 and convertible cylinder 15, it is gripping-changed to the grippers 32a of the convertible cylinder 15. When the convertible cylinder 15 further pivots, both the grippers 32a and 32b of the convertible press mechanisms 33a lie down in the notch of the convertible cylinder 15, and the trailing edge of the paper sheet P is gripping-changed from the grippers 32a to the grippers 32b. In this state, when the convertible cylinder 15 further rotates, the paper sheet P is released from the grippers 30 of the chucking cylinder 13. Thus, the paper sheet P to be conveyed with its leading edge being gripped by the grippers 32b of the convertible cylinder 15 is turned over.
At this time, the air 26b and air 27b from the blowing ports 26a and 27a of the air nozzles 26 and 27 are blown toward the center of the paper sheet P at a gap between the outer surface of the chucking cylinder 13 and the paper sheet P which is being separated from the outer surface of the chucking cylinder 13 so as to be turned. Therefore, due to the pressure of the air 26b and air 27b, the paper sheet P does not come into tight contact with the outer surface of the chucking cylinder 13 but is separated. This operation will be described in detail hereinafter.
The blowing port 26a of the air nozzle 26 and the blowing port 27a of the air nozzle 27 are set at slightly different horizontal angles. Thus, the air 26b from the blowing port 26a and the air 27b from the blowing port 27a are blown out toward two positions on the center in the widthwise direction of the paper sheet P which are shifted from each other by a length “L” in the sheet convey direction. Therefore, first, that portion of the paper sheet P which ranges from the central portion to near the trailing edge in the sheet convey direction is separated from the outer surface of the chucking cylinder 13 by the air 26b from the blowing port 26a. Then, the trailing edge of the paper sheet P is completely separated from the outer surface of the chucking cylinder 13 by the air 27b from the blowing port 27a.
The air nozzles 26 and 27 are attached to the frames 25 with no relation to the rotation of the chucking cylinder 13. The blowing times of the air 26b and air 27b to the paper sheet P thus prolong so that a sufficient quantity of air can be blown. Therefore, the paper sheet P can be reliably separated from the outer surface of the chucking cylinder 13. Accordingly, a gap is reliably formed between the separated paper sheet P and a subsequent paper sheet P. Thus, the sheets do not come into contact with each other, and the printing surfaces of the paper sheets P can be prevented from being damaged.
As the blowing port 27a is arranged at a position higher than the blowing port 26a by “H”, the two air flows, i.e., the air 26b and air 27b blown out from the outer sides of the two ends of the chucking cylinder 13 toward the center do not collide against each other. The quantity of air blown to the paper sheet P does not become unequal among the two end sides and the central portion in the widthwise direction of the paper sheet P. The paper sheet P thus does not flutter or wave but behaves evenly in the widthwise direction. Consequently, the paper sheet P can be reliably separated from the surface of the chucking cylinder 13, so that damage, rubbing, or wrinkles can be prevented from occurring on the printing surface of the paper sheet P.
Regarding the height difference “H”, if the cylinder length of the chucking cylinder 13 is comparatively small, the opposing blowing ports 26a and 27a are close to each other. In this case, the air 26b from the blowing port 26a and the air 27b from the blowing port 27a tend to adversely affect each other readily. To prevent this, the height difference between the blowing ports 26a and 27a needs to be increased. If the cylinder length of the chucking cylinder 13 is comparatively large, the opposing blowing ports 26a and 27a are spaced apart from each other. In this case, the air 26b from the blowing port 26a and the air 27b from the blowing port 27a less adversely affect each other. Therefore, the height difference between the blowing ports 26a and 27a can be decreased.
The present inventor repeatedly conducted various experiments by changing the cylinder length of the chucking cylinder 13 and the thickness of the paper sheet P to be conveyed, and confirmed the following fact. That is, when the height difference “H” was set within the range of 10 mm to 70 mm, the paper sheet P could be reliably separated from the chucking cylinder 13 in accordance with the cylinder length and the thickness of the paper sheet P.
The paper sheet P separated from the chucking cylinder 13 and gripped by the grippers 32b of the convertible cylinder 15 is regulated from fluttering by the air blown by the air nozzle 22, and then conveyed as it is urged against the outer surface of the convertible cylinder 15 in tight contact by the air discharged from the air nozzles 23 and 24. When the grippers 32b reach the opposing point of the impression cylinder 7c, the paper sheet P is gripped by the grippers of the impression cylinder 7c. Then, the printing unit 3c prints the reverse surface of the paper sheet P with the first color.
In the above embodiment, the air nozzles 26 and 27 are attached to the pair of frames 25, but they may be attached to the machine base 16, and various design changes can thus be made. In the above embodiment, a paper sheet is used as the sheet to be conveyed. The sheet can be of any type as far as it is a sheet-type object, e.g., a polyvinyl chloride sheet or film, with an obverse surface that can be printed.
A modification of the air nozzles 26 and 27 described above will be described. In this modification, air nozzles 126 and 127 have variable-height blowing ports 126a and 127a. Angles α and β in the vertical and horizontal directions of each of the blowing ports 126a and 127a are variable. As the air nozzles 126 and 127 have similar structures, the structure of the air nozzle 127 will be described hereinafter as a representative.
The air nozzle 127 comprises a proximal-end-side cylindrical member 127b, a distal-end-side cylindrical member 127c, a cylindrical neck member 127d, and an elliptic spherical head member 127e. The cylindrical member 127c has an outer surface that slides on the inner surface of the cylindrical member 127b in the axial direction. The neck member 127d has an outer surface that slides on the inner surface of the distal end portion of the cylindrical member 127c in the circumferential direction. The head member 127e has a rear portion which is supported by the neck member 127d to be vertically pivotal. The head member 127e also has a blowing port 127a at its distal end which discharges air directively.
The cylindrical member 127c is moved forward from and backward into the cylindrical member 127b to adjust the height of the blowing port 127a. After the adjustment, a set screw 141 is fastened to fix the cylindrical member 127c to the cylindrical member 127b. The cylindrical member 127b, cylindrical member 127c, and set screw 141 constitute a height adjusting mechanism 128 for the blowing port 127a.
The neck member 127d is pivoted by the distal end portion of the cylindrical member 127c to adjust the angle β of the blowing port 127a in the horizontal direction. After the adjustment, a set screw 142 is fastened to fix the neck member 127d to the cylindrical member 127c. The cylindrical member 127c, neck member 127d, and set screw 142 constitute a horizontal blowing angle (β) adjusting mechanism.
The head member 127e is pivoted about a screw 143 at the rear end portion of the neck member 127d as a fulcrum to adjust the angle a of the blowing port 127a in the vertical direction. After the adjustment, the screw 143 is fastened to fix the head member 127e to the neck member 127d. The neck member 127d, head member 127e, and screw 143 constitute a vertical blowing angle (α) adjusting mechanism. The set screws 141, 142, and 143 may be omitted if the engaging frictional force between the two members is large.
In place of the height adjusting mechanism 128 with which the operator performs height adjustment manually, an automatically controllable height adjusting device, e.g., an air cylinder having a rod which is movable forward/backward, can be used. In this case, when the thickness of a paper sheet to be conveyed is input, the forward/backward amount of the rod is controlled to automatically adjust the heights of the blowing ports 126a and 127a.
While a case has been described wherein the height adjusting mechanism comprises the two cylindrical members 127b and 127c and set screw 141, the present invention is not limited to this. Any structure will do as far as it can adjust the height of the blowing port 127a mechanically. The horizontal angle of the head member 127e is adjustable with respect to the neck member 127d. Alternatively, the neck member 127d and head member 127e may be integrally formed, and the cylindrical member 127c may be formed pivotal in the circumferential direction with respect to the cylindrical member 127b, to adjust the horizontal angle. In this case, the cylindrical member 127b, cylindrical member 127c, and set screw 141 constitute a height/horizontal angle adjusting mechanism. The set screw 142 then becomes unnecessary.
As has been described above, according to the present invention, the direction in which the air blowing means blows air can be held constant with no relation to the rotation of the upstream transport cylinder. Thus, the blowing time of air to the sheet in tight contact with the upstream transport cylinder can be prolonged. Therefore, the sheet which is to be gripping-changed from the upstream transport cylinder to the downstream transport cylinder in the sheet convey direction so as to be turned over can be reliably separated from the surface of the upstream transport cylinder. Since the air blowing means is fixed to the apparatus, a hose or the like to supply air to the air blowing means need not be provided in the cylinder. Thus, the structure of the cylinder does not become complicated.
As the two air blowing means have different heights, the two air flows directed from the outer sides of the two ends of the transport cylinder to the central side do not collide against each other. Thus, the quantity of air blown to the sheet does not become unequal among the two end sides and the central portion in the widthwise direction of the sheet. Consequently, the sheet thus does not flutter or wave but can be separated from the surface of the upstream transport cylinder. Thus, damage, rubbing, or wrinkles can be prevented from occurring on the printing surface of the sheet.
Number | Date | Country | Kind |
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348551/2004 | Dec 2004 | JP | national |
370766/2004 | Dec 2004 | JP | national |