JP2009040047A - State switching method and apparatus for rolled paper rotary printing machine - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To increase the uptime ratio by reducing the burden on an operator, and at the same time, eliminating wastes of printing materials as much as possible. <P>SOLUTION: A rolled paper rotary printing machine is equipped with A-side and B-side stacker bundler apparatus 115A and 115B. The rolled paper rotary printing machine is equipped with counters 62A and 62B, a picture setting means, and a controlling means. In this case, the counters 62A and 62B count the number of signatures which are discharged to the A-side and B-side stacker bundler apparatus. The picture setting means sets whether the signatures which have been discharged in two rows have the same picture or not. The controlling means stops the printing by the printing unit conforming to the total value of the number of signatures which have been discharged to the A-side and B-side stacker bundler apparatus when the setting by the picture setting means is the same picture. At the same time, the controlling means makes an automatic pasting apparatus 36, automatic printing plate replacing apparatus 124a and 124b, and a folding specification switching apparatus 126 and so forth automatically operated. In this case, the automatic pasting apparatus 36 automatically switches the state of the rolled paper rotary printing machine from the state of printing stopped this time to a next printing state. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a state switching method and apparatus for a web rotary press.

  Conventionally, in a web rotary printing press in which signatures discharged from a folding machine are conveyed to a stacker / bundler device by a conveyor, and are stacked and banded (bundled) from a small bundle to a large bundle with this stacker / bundler device, The operator counts the number of bundles ejected from the stacker and bundler and stacked on the pallet. When the number of bundles reaches a predetermined number, the web rotary press is manually stopped, and then the operator rolls the web. Each device for setting the printing press according to the next printed matter is configured by a switch operation (see Patent Document 1).

  Conventionally, web printing is performed by cutting the web in the left-right direction (direction parallel to the web conveyance direction) with a slitter, and conveying the signatures ejected from the folding machine into two different stackers and bundlers. In the machine, the number of printing defects that occur due to ink dripping or Hickey (a part of the pattern that has become white due to paper dust, etc.) is different on the left and right, and the transport path of the printed material after being cut left and right The number of printed papers collected by both stacker and bundler devices is not necessarily the same because they are different from each other and the number of waste paper generated during conveyance is also different.

JP 2001-322252 A Japanese Unexamined Patent Publication No. 63-282053 JP 2000-130538 A JP 2000-095431 A

  By the way, in the conventional web-type rotary printing press as described above, when the operator counts the number of bundles discharged from the stacker and bundler device and loaded on the pallet, the number of bundles reaches a predetermined number. Since the web rotary press was manually stopped, and after this stop, the operator had to set each device to set the web rotary press according to the next printed matter by switch operation. In other words, printing materials are wasted, and printing materials are wasted. In combination with the above-described manual operation, the operating rate is reduced and the operator is burdened.

  Also, when the web is cut in the left-right direction with a slitter, the number of prints collected by both stacker and bundler devices is not necessarily the same. When the number of bundles of the smaller printed matter reaches the set number, the printing on the web rotary press is stopped, so more printed matter is printed than necessary, and printing materials are wasted. There was a problem that it took extra time.

  SUMMARY OF THE INVENTION Accordingly, an object of the present invention is to provide a state switching method and apparatus for a web-fed rotary printing press that can reduce the burden on an operator, eliminate waste of printing materials as much as possible, and improve the operating rate. .

In order to solve the above problems, a method for switching the state of a web rotary press according to the present invention is as follows:
Printing means for printing on a web,
Cutting means for cutting the printed matter printed by the printing means in a direction perpendicular to the conveyance direction of the web;
A web-fed rotary printing press comprising a paper discharge means for discharging the cut printed matter to a post-processing device for further processing;
Comprising a counting means for counting the number of printed matter discharged to the post-processing device,
In response to the signal from the counting means, the printing means stops printing,
At least one of automatic switching devices for automatically switching the state of the web rotary press to the next printing state is automatically operated.

  The post-processing device is a stacker and bundler device.

Printing means for printing on a web,
First cutting means for cutting the printed matter printed by the printing means in a direction parallel to the web transport direction;
A second cutting means for cutting the printed material cut by the first cutting means in a direction perpendicular to the conveyance direction of the web;
Paper discharge means for discharging the printed material cut by the second cutting means to different paper discharge devices,
In a web printing press equipped with
Counting means for counting the number of printed matter discharged to each paper discharge device;
Pattern setting means for setting whether the cut printed material is the same pattern;
With
When the setting of the picture setting means is the same picture, the printing means stops printing based on the total value of the number of printed matter discharged to each paper discharge device,
At least one of automatic switching devices for automatically switching the state of the web rotary press to the next printing state is automatically operated.

The web rotary press is
A strip continuous supply means for pasting the strip of the new web roll to the strip of the old web roll and continuously feeding the strip,
Plate changing means for changing the plate supported on the plate cylinder;
Folding machine folding specification switching means for switching the folding machine state according to the next printing folding specification,
With
When switching the state of the web rotary printing press to the next printing state, the automatic switching devices of the strip continuous supply means, the plate changing means, and the folding specification switching means of the folding machine are operated in a predetermined order. It is characterized by that.

  It is characterized in that at least one of the automatic switching devices is automatically operated when the total value of the number of printed materials discharged to each of the paper discharge devices becomes equal to or greater than the set required number of prints.

  When the setting of the design setting means is not the same design, when the number of printed materials discharged to each of the paper discharge devices exceeds the set required number of prints, at least one of the automatic switching devices is automatically operated. It is characterized by making it.

In order to solve the above problems, a state switching device for a web-fed rotary printing press according to the present invention,
Printing means for printing on a web,
Cutting means for cutting the printed matter printed by the printing means in a direction perpendicular to the conveyance direction of the web;
A web-fed rotary printing press comprising a paper discharge means for discharging the cut printed matter to a post-processing device for further processing;
Counting means for counting the number of printed matter discharged to the post-processing device;
Control for automatically operating at least one of automatic switching devices for automatically stopping the state of the web-fed rotary printing press to the next printing state while stopping printing of the printing means in response to a signal from the counting means Means,
It is provided with.

  The post-processing device is a stacker and bundler device.

Printing means for printing on a web,
First cutting means for cutting the printed matter printed by the printing means in a direction parallel to the web transport direction;
A second cutting means for cutting the printed material cut by the first cutting means in a direction perpendicular to the conveyance direction of the web;
Paper discharge means for discharging the printed material cut by the second cutting means to different paper discharge devices,
In a web printing press equipped with
Counting means for counting the number of printed matter discharged to each paper discharge device;
Pattern setting means for setting whether the cut printed material is the same pattern;
When the setting of the picture setting means is the same picture, printing of the printing means is stopped based on a total value of the number of printed matter discharged to each paper discharge device, and the state of the web rotary press is changed to the following: Control means for automatically operating at least one of automatic switching devices for automatically switching to a printing state;
It is provided with.

The web rotary press is
A strip continuous supply means for pasting the strip of the new web roll to the strip of the old web roll and continuously feeding the strip,
Plate changing means for changing the plate supported on the plate cylinder;
Folding machine folding specification switching means for switching the folding machine state according to the next printing folding specification,
When switching the state of the web rotary printing press from the currently stopped printing state to the next printing state, the automatic switching devices of the strip continuous supply means, the plate changing means, and the folding specification switching means of the folding machine are previously set. Control means for operating in a defined order;
It is provided with.

  The control means automatically operates at least one of the automatic switching devices when the total value of the number of printed matter discharged to each of the paper discharge devices is equal to or more than a set required number of prints. And

  When the setting of the picture setting means is not the same picture, the control means is configured to output at least one of the automatic switching devices when the number of printed materials discharged to each paper discharge device exceeds a set required number of prints. Is automatically operated.

  According to the configuration of the present invention, the printed matter collected by the post-processing device such as a stacker / bundler device is counted by a counting unit such as a counter, and the post-processing of the stacker / bundler device or the like is performed when the counted number becomes the same as the set number. The apparatus outputs a print stop signal, stops printing of the web rotary press in response to the print stop signal, and sets at least one of the automatic switching devices to set the setting of the web rotary press according to the next printed matter. Since the printer is automatically operated, the burden on the operator can be reduced by automation, and the web rotary press can be stopped as quickly as possible. Can be improved.

  In addition, if the web pattern is the same pattern in a web printing press that cuts the web in the left-right direction with a slitter, etc., and discharges it to a separate post-processing device such as a stacker / bundler device or a paper ejection device, each stacker / bundler device, etc. At least one of the automatic switching devices for stopping the printing of the web rotary press by the total value of the printed materials transmitted from the post-processing device and the paper discharge device and setting the setting of the web rotary press according to the next printed material. Since the printer is automatically operated, the burden on the operator can be reduced by automation, and the web rotary press can be stopped as soon as possible. The rate can be improved.

  Hereinafter, a state switching method and apparatus for a web rotary printing press according to the present invention will be described in detail with reference to the accompanying drawings.

  1A and 1B are block diagrams of a control device for a web rotary press showing Embodiment 1 of the present invention, FIGS. 2A and 2B are block diagrams of a stacker and bundler control device, and FIGS. 3A to 3D are web rotary presses. 4A to 4D are operation flow diagrams of the control device of the web rotary press, FIGS. 5A to 5D are operation flow diagrams of the control device of the web rotary press, and FIGS. 6A to 6C are FIG. 7A and 7B are operation flow diagrams of the stacker and bundler control device, FIGS. 8A to 8E are operation flow diagrams of the stacker and bundler control device, and FIGS. 9A and 9B are FIG. FIG. 32 is a schematic configuration diagram of a web-fed rotary printing press, FIG. 33 is an explanatory diagram of a paper feeding device, and FIG. 34 is an explanatory diagram of a printing unit. 35 is an explanatory diagram of an ink film thickness preparation device (ink supply device), FIG. 36 is an explanatory diagram of cam switching, FIG. 37 is an explanatory diagram of guide switching, FIG. 38 is an explanatory diagram of a slitter, and FIG. 39 is a web-fed rotary printing press. FIG. 40 is an explanatory diagram of a reject device, FIG. 41 is an explanatory diagram of a small bundle paper supply confirmation sensor, FIGS. 42A and 42B are explanatory diagrams of banding specifications, and FIG. FIG. 4 is an operation flowchart of a job switching sequence.

  As shown in FIG. 32, the web rotary press 100 includes a paper feeding device 101, a printing unit (printing means) 102, a drying device 103, a cooling device 104, a web pass device 105, a drag device 106, and a folder 107. Prepare.

  As shown in FIG. 33, the sheet feeding device 101 has two web rolls 201 and 202 wound in a roll shape mounted on both ends of a turret arm 204, and the turret arm 204 can be swung around a central axis 203. When the web (band) W is unwound from one of the web rolls 201 and approaches the end, the web W from the next web roll 202 is pasted and connected to the next printing unit 102 continuously. An automatic paste device (strip continuous supply means) 36 is provided.

  The printing unit 102 is composed of four color printing units 102a to 102d. Each of the printing units 102a to 102d has rubber cylinders 205a and 205b and a plate cylinder 206a with respect to a horizontally running web W as shown in FIG. , 206b are arranged symmetrically in the vertical direction, and blanket cleaning devices 121a, 121b are provided corresponding to the rubber cylinders 205a, 205b, while automatic plate changers (APCs) are provided corresponding to the plate cylinders 206a, 206b. (Exchange means) 124a and 124b are provided. The blanket cleaning devices 121a and 121b are devices for removing foreign matters such as ink scum by bringing a brush or cloth into contact with the rubber cylinders 205a and 205b.

  The upper automatic plate changer 124a is provided with a guide frame 210a so as to be pivotable about the support shaft 209a, and can be moved from the standby position to the plate change position by the actuator 211a as indicated by a broken line in the figure. The guide frame 210a is provided with a holder 212a for holding an old version or a new version. Therefore, after the guide frame 210a is moved to the plate replacement position, the old plate is disengaged from the plate cylinder 206a, and the plate cylinder 206a is rotated in the reverse direction, thereby guiding the old plate along the guide frame 210a and an actuator (not shown). The old version can be raised by expanding and contracting. Thereafter, the new plate is supplied to the plate cylinder 206a along the guide frame 210a, and the plate cylinder 206a is rotated forward to mount the new plate on the plate cylinder 206a.

  Similarly, the lower automatic plate changer 124b is provided with a guide frame 210b so as to be pivotable about the support shaft 209b, and is moved from the standby position to the plate change position by the actuator 211b as indicated by a broken line in the figure. The guide frame 210a is provided with a holder 212b for holding an old version or a new version. Therefore, after the guide frame 210b is moved to the plate replacement position, the old plate can be lowered along the guide frame 210b by releasing the engagement of the old plate from the plate cylinder 206b and reversely rotating the plate cylinder 206b. Thereafter, the new plate is supplied to the plate cylinder 206b along the guide frame 210b, and the plate cylinder 206b is rotated forward to mount the new plate on the plate cylinder 206b.

  Furthermore, an ink film thickness creating device (ink supply device) 120 as shown in FIG. 35 is provided for the printing plates on the plate cylinders 206a and 206b. The ink film thickness creating device 120 supplies the ink 217 in the ink fountain 216 to the ink fountain roller 218 by adjusting the opening degree of the ink fountain keys 215-1 to 215-n, and the ink supplied to the ink fountain roller 218 is transferred to the ink. The ink is supplied to the printing plate 221 through the ink roller group 220 by the calling operation of the roller 219. In parallel with this ink supply, the dampening water 222 is supplied to the printing plate 221 via the water supply roller group 223. In the ink film thickness creating device 120, when the printing plate 221 is exchanged from the old version to the new version, the opening degree of the ink fountain keys 215-1 to 215-n and the rotation amount of the ink fountain roller 218 are changed to values according to the design of the new version. The main printing data such as the supply amount of the dampening water 222 is preset as will be described later.

  The drying device 103 is a device that heats and dries the web W printed through the printing unit 102. The cooling device 104 is a device that cools the web W after passing through the drying device 103. The web pass device 105 and the drag device 106 are devices that change the direction and the like in order to control the position and tension of the web W.

  The folding machine 107 is an apparatus that cuts and folds the web W after drying and cooling. For example, the former is folded in half with the former in the width direction, cut into a predetermined length with a cutting cylinder (second cutting means), or the folded signature is folded in parallel with the folding cylinder. In other words, it is a device that folds parallel folded signatures in the orthogonal direction with a chopper, and has various structures according to combinations of cutting and folding.

  Also, the folding machine 107 is provided with a folding specification switching device (folding machine folding specification switching means) 126 (refer to FIG. 1B) that includes folding cylinder / cylinder cylinder phase change and cam / guide switching. Folding cylinder / cylinder phase change means changing the phase of the gripping plate of the gripping cylinder with respect to the needle and knife of the folding cylinder in accordance with parallel 1 diffraction or parallel 2 diffraction. As shown in FIG. 4, there is an example of changing by a gear transmission mechanism. Cam / guide switching is cam switching for switching the phase of the cam mechanism for switching the operation timing of the gripping claws, knives and needles provided on the cutting cylinder, folding cylinder and rod cylinder, and parallel parallel diffraction. It is a general term for guide switching of a guide mechanism for switching between two diffraction and delta folding.

  As shown in FIG. 36, the cam switching includes a cam holder 230 that is rotatably supported and has protrusions 230a and 230b on the outer peripheral surface, and an annular cam that is attached to the cam holder 230 and has a predetermined outer peripheral surface. 231; a cam follower 232 that transfers on the outer peripheral surface of the cam 231; and a link plate 233, a lever 234, an air cylinder 235, and the like that are connected to the protruding portion 230b of the cam holder 230 to rotate the cam holder 230. A first stopper 236 that restricts rotation of the cam 231 to one side accompanying the extension of the air cylinder 235, and a second stopper 237 that restricts rotation of the cam 231 to the other side accompanying contraction of the air cylinder 235; The protrusion 230a of the cam holder 230 is restricted from rotating to the other side by the second stopper 237. Is made and a third stopper 238 for urging the rotation direction is restricted by the second stopper 237 (see Patent Document 3).

  As the guide switching, as shown in FIG. 37, in the parallel folding device of the folding machine in which the first holding cylinder 240 and the second holding cylinder 241 are arranged with their peripheral surfaces in contact with each other, the first holding cylinder 240 is arranged. When the belt 243 is hung between the rollers 242a to 242d parallel to this and the predetermined roller 242d is moved so that the belt 243 is folded once in parallel, the first holding cylinder 240 is replaced with the second holding cylinder 241. On the other hand, the front end of the signature is switched from the first holding cylinder 240 to a guide position for guiding it to the second holding cylinder 241, and conversely, the first holding cylinder 240 and the second holding cylinder 241 are folded in parallel at the time of parallel double diffraction or delta folding. In some cases, the second holding cylinder 241 is switched to a retracted position (see Patent Document 4).

  In addition, a dancer device 123a is disposed between the paper feeding device 101 and the printing unit 102, and a dancer device 123b is disposed between the printing unit 102 and the drying device 103 (final unit). Yes. The dancer devices 123a and 123b are devices that take up the slack of the web when the printing unit 102 rotates forward and backward by winding the web W between three rolls and moving the center roll up and down. Although not shown, these devices 101 to 107 are connected by a drive shaft and driven by a main motor provided in the printing unit 102. Also, the printing unit 102 and the (final unit) dancer It can be disconnected by ON / OFF of a driving clutch provided between the device 123b.

  In this embodiment, the drag device 106 has a disk-shaped slitter (first cutting means) 109 swinging in an annular groove provided at the center in the width direction of the drag roller 108, as shown in FIG. The web W, which is detachably engaged through the free arm 110 and pulled out by the drag roller 108 through the guide rollers 111a to 111e, is cut into the web W1 and the web W2 at the center in the width direction, and then the drag rollers 112, 113 is conveyed to the folding machine 107 side through different conveyance paths, and so-called one web and two lines are arranged.

  Further, as shown in FIG. 39, the signature (printed matter) discharged from the folding machine 107 of the web rotary printing press 100 is placed on both sides of A and B by two transport paths (discharge means) 114A and 114B including a conveyor. The stacker / bundler device (paper discharge device; post-processing device) 115A, 115B is conveyed.

  The stacker / bundler devices 115A and 115B align the signatures ejected from the folding machine 107 and stack them as small bundles, stack a certain amount of these small bundles and carry them out as large bundles. 42A and 42B show a large bundle of banding specifications. 42A shows one hook of the band 116, and FIG. 42B shows two hooks of the band 116.

  In addition, as shown in FIG. 40, each stacker / bundler device 115A, 115B has a waste paper that does not need to be passed through the machine by raising the tip of the entrance conveyor 118 provided at the forefront of the device body 117. Rejecting devices 64A and 64B (see FIG. 2B) are provided for discharging the gas etc. to a waste basket or the like (not shown).

  Furthermore, as shown in FIG. 41, each stacker / bundler device 115A, 115B is provided with a small bundle portion paper supply confirmation sensor 63A, 63B (see FIG. 2A) located immediately before the small bundle portion 119. The small bundle paper supply confirmation sensors 63A and 63B are photoelectric sensors, and output signals only while being shielded by the signature Wa on the conveyor. This small bundle paper supply confirmation sensor 63A is provided at one input end of an AND circuit (see FIG. 2A) provided in front of the current sheet count counter (counting means) 62A, 62B (see FIG. 2A). 63B, and the other input end is connected to a print number counting sensor 35 (see FIG. 2A) of the web rotary press. Therefore, via this AND circuit, the current normal paper sheet count counters 62A and 62B have a webbing rotary printing press only while the small bundle paper supply confirmation sensors 63A and 63B are shielded by the signature Wa on the conveyor. A one-part / one-count signal is input from the print sheet count sensor 35, and the current normal sheet count counters 62A and 62B are incremented based on this signal.

  In the present embodiment, the signatures discharged to the stacker / bundler devices 115A and 115B by the control device (control means) 10 and the stacker / bundleler control device (control means) 50 of the web-fed rotary printing press, which will be described later, respectively. In the case of the same pattern, the web page rotary printing press 100 is based on the total number of signatures transmitted from the stacker and bundler devices 115A and 115B. If the number of signatures transmitted from each of the stacker and bundler devices 115A and 115B exceeds the set required number of prints, the printing of the web rotary press 100 is stopped. Printing is stopped.

  In conjunction with this, the setting of the web rotary press 100 is set in accordance with the next printed matter, and the ink film thickness creating device 120, the auto paste device 36, the blanket cleaning devices 121a and 121b, the web preset device 122 ( FIG. 43 shows automatic switching devices such as dancer devices 123a and 123b, automatic plate changers 124a and 124b, infeed device 125 (see FIG. 1B), folding specification switching device 126, drying device 103, and the like. It operates according to the job switching sequence.

  That is, after the printing completion operation is started in step P1, ink removal is performed by the ink film thickness creating device 120 in step P2a, and then in steps P2b and P2c, the rubber cylinder 205a by the blanket cleaning devices 121a and 121b. 205b, the automatic pasting device 36 moves the new web roll 202 to the paper splicing standby position, and aligns the paper edge between the old web roll 201 and the new web roll 202. Ink removing means that the ink transfer roller 219 stops the calling operation to remove the ink film thickness distribution according to the old plate pattern formed on the ink roller group 220 and is finally required during printing. The minimum ink film thickness that can be achieved.

  Next, in Steps P3a to P3c, the paper pasting from the old web roll 201 to the new web roll 202 by the auto paste device 36, the adjustment of each part accompanying the paper width change by the web preset device 122, and the ink film thickness A pot key control device (PQC) preset by the creation device 120 is performed. By the fountain key control device (PQC) preset, the opening degree of each ink fountain key 215-1 to 215-n is adjusted to the opening degree according to the new pattern.

  Next, after the plate is changed from the old version to the new version in cooperation with the dancer devices 123a and 123b and the automatic plate changers (APC) 124a and 124b in step P4, the folding specification switching device 126 performs the above-described change in step P5. Perform various types of switching.

  Next, after the standby operation of the dryer is started by the drying device 103 in step P6, pre-inking is started by the ink film thickness creating device 120 in step P7, and then printing is started, so that job switching is performed in step P8. Complete and return to step P1. In this pre-inking, the opening of the ink fountain keys 215-1 to 215-n and the rotation amount of the ink fountain roller 218 are changed to the new pattern according to the main printing data preset in the ink film thickness creating device 120 corresponding to a new job. The ink transfer roller is called in a predetermined number of times, and the ink transfer roller 220 is kept in the ink roller group 220 for the minimum ink film thickness required during printing. The ink film thickness distribution corresponding to the pattern of the new version is superimposed.

  As shown in FIGS. 1A and 1B, the control device 10 of the web rotary press for controlling each automatic switching device described above includes a CPU 11, a ROM 12, a RAM 13, input / output devices 15a to 15m, and an interface 16 together. Connected with (bus).

  Also, the BUS (bus line) includes a data storage memory M1, a target print number storage memory M2, a count value storage memory M3 of a current print number count counter, and a main printing stop position storage memory. M4 and the main printing restart position storage memory M5 are connected.

  Further, the current paper width storage memory M32, the folding specification storage memory M34, the set rotational speed storage memory M35, the operation state storage memory M36 of the auto-paste device, and the previous rotational speed storage are included in the BUS (bus). The memory M37, the memory for storing the rotational speed correction value M38 during deceleration, and the memory for storing the current rotational speed M39 are connected.

  Further, the BUS (bus bar) includes a rotational speed storage memory M80, a command rotational speed storage memory M81, a slow rotational speed storage memory M82, an operation status storage memory M83 of the web preset device, and an ink for blanket cleaning. An operation state storage memory M84 of the film thickness creation device, a rotational speed correction value storage memory M89 at the time of acceleration, and a rotational speed storage memory M90 at the start of pre-inking are connected.

  The input / output device 15a includes an identical picture setting switch 26, a setting completion switch 27, a print start switch 28, a regular paper switch (self-holding switch) 29, an input device 30 such as a keyboard, and a display 31 such as a CRT or display. An output device 32 such as a printer or a floppy disk (registered trademark) drive is connected.

  A target print number setting device 33 is connected to the input / output device 15b. A paper width setting device 41 is connected to the input / output device 15c. A folding specification setting device 42 is connected to the input / output device 15d. A rotation speed setting unit 43 is connected to the input / output device 15e.

  The input / output device 15f is connected with a sensor 35 for counting the number of printed sheets of a web rotary press. The input / output device 15g is connected with a counter 34 for counting the current number of printed sheets, and the counter 34 for counting the number of currently printed sheets is connected with a sensor 35 for counting the number of printed sheets of a web rotary press. The input / output device 15h is connected to a counter 34 for counting the current number of printed sheets, to which a reset signal and an enable signal are output.

  The auto paste device 36 and the print quality inspection device 37 described above are connected to the input / output device 15i, from which a waste paper signal is input.

  A driving motor 45 is connected to the input / output device 15j via a D / A converter 17 and a driving motor driver 44. A driving motor rotary encoder 46 connected to the driving motor 45 is connected to the driving motor driver 44.

  The input / output device 15m includes a first color printing unit (operation panel) 102a, a second color printing unit (operation panel) 102b, a third color printing unit (operation panel) 102c, and a fourth color printing unit (operation panel) 102d. Is connected.

  The interface 16 includes a stacker and bundler control device 50, an ink film thickness preparation device 120, an auto paste device 36, a blanket cleaning device 121a and 121b, a web preset device 122, dancer devices 123a and 123b, and an automatic plate changer 124a. , 124b, the infeed device 125, the folding specification switching device 126, and the drying device 103 are connected.

  On the other hand, as shown in FIGS. 2A and 2B, the stacker / bundler control device 50 includes a CPU 51, a ROM 52, a RAM 53, input / output devices 54, 55A, 56A, 55B, 56B, 57, and an interface 58, all of which are buses. ) And connected.

  The BUS (bus line) includes a data storage memory M40, a target print number storage memory M41, a count value M storage memory M42, a count value N storage memory M43, and a final printing stop position storage. A memory M44, a full-printing resume position storage memory M45, and a current print number storage memory M46 of the web rotary press are connected.

  Further, in the BUS (bus line), the count value MM storage memory M47, the MM-th final printing stop position storage memory M48, the number-of-sheets storage memory M49 up to the A-side rejection device, and the A-side MM-th rejection start. The position storage memory 50 is connected to the number-of-sheets storage memory M51 up to the B-side reject device and the B-side MM-th reject start position storage memory M52.

  Further, the BUS (bus line) includes a count value NN storage memory M53, an NNth final printing restart position storage memory M54, an A side NNth rejection completion position storage memory M55, and a B side NNth rejection. A memory M57 for storing the number of sheets up to the memory M56 for completion position storage and a sensor for confirming supply of a small bundle of paper on the A side, an M-th count stop position storage memory M58 on the A side, and a supply of small bundle of paper on the B side A memory M59 for storing the number of sheets up to the sensor is connected.

  Further, the BUS (bus) includes the B-side MMth count stop position storage memory M60, the A-side NNth count restart position storage memory M61, and the B-side NNth count restart position storage memory M62. A count value storage memory M63 of the current sheet count counter on the A side and a count value storage memory M64 of the current sheet count counter on the B side and a current total sheet count storage memory M65 A target total print number storage memory M66 is connected.

  An input device 59 such as a keyboard, a display device 60 such as a CRT or a display, and an output device 61 such as a printer or a floppy disk (registered trademark) drive are connected to the input / output device 54.

  The A-side current sheet number counting counter 62A is connected to the input / output device 55A, and the A-side sheet number counting counter 62A on the A side is connected to the A-side small bundle paper via an AND circuit. The sensor 63A for supply confirmation and the sensor 35 for counting the number of printed sheets of the web rotary press are connected. The input / output device 56A is connected to a current sheet count counter 62A on the A side, to which a reset signal and an enable signal are output.

  The input / output device 55B is connected to a B-side current sheet number counting counter 62B on the B side. The B-side current sheet number counting counter 62B is connected to the B-side small bundle sheet via an AND circuit. The supply confirmation sensor 63B is connected to the print number counting sensor 35 of the web rotary press. The input / output device 56B is connected to a current normal sheet count counter 62B on the B side, to which a reset signal and an enable signal are output.

  The input / output device 57 is connected to the A-side reject device 64A and the B-side reject device 64B, and a reject signal is output to these.

  The interface 58 is connected to the control device 10 of the web rotary press.

  The control operation of the control device 10 of the web rotary press having the above-described configuration will be described in detail with reference to the operation flowcharts of FIGS. 3A to 3D, 4A to 4D, 5A to 5D, and 6A to 6C.

  First, after initialization processing in step P1, it is determined in step P2 whether or not the setting completion switch 27 is ON. If yes, the print start switch 28 is turned ON in step P3, and printing is started in step P4. .

  Next, in step P5, a reset signal and an enable signal are output to the current print number counting counter 34. Then, in step P6, the output of the reset signal to the current print number counting counter 34 is stopped.

  Next, in step P7, data indicating whether or not the picture is the same is read from the memory M1, and then in step P8, the target print number is read from the memory M2. Next, in step P9, the data indicating whether the picture is the same and the target print number are transmitted to the stacker / bundler control device 50.

  Next, in step P10, the stacker / bundler control device 50 transmits the data indicating whether the images are the same and the target print number reception confirmation signal. Then, in step P11, the adjustment for printing is completed, and printing of the normal paper is started. For example, when the regular paper switch (self-holding switch) 29 is turned on by the operator, a final printing start signal is transmitted to the stacker / bundler control device 50 in step P12.

  Next, when the reception confirmation signal for the main printing start signal is transmitted from the stacker / bundleer control device 50 in step P13, it is determined in step P14 whether or not the output of the print sheet count sensor 35 of the web rotary press is ON. To do.

  Next, if yes in Step P14, the count value is read from the current print number counting counter 34 and stored in the memory M3 in Step P15. If not, the process proceeds to Step P17 described later.

  Next, in step P16, the current count value of the counter 34 for counting the number of prints is transmitted to the stacker / bundler control device 50, and then whether or not a print completion signal is transmitted from the stacker / bundler control device 50 in step P17 described above. If YES in step P59, the flow shifts to step P59 described later.

  If NO in step P2, it is determined in step P18 whether or not the same picture setting switch 26 is ON. If yes, the contents of the data storage memory M1 indicating whether or not the same picture is set are read in step P19. If not, the process proceeds to Step P23 described later.

  Next, in step P20, it is determined whether or not the contents of the data storage memory for the same picture = 0. If yes, 1 (identical) is overwritten in the data storage memory M1 for the same picture in step P21. Then, the process proceeds to step P23. If not, the data storage memory M1 indicating whether or not the same picture is overwritten is overwritten with 0 (different) in step P22, and the process proceeds to step P23.

  Next, it is determined whether or not the target print number setting device 33 has been input to the target print number setting device 33 in step P23 described above. If yes, the setting value of the target print number setting device 33 is read and stored in step P24. After overwriting the memory M2, the process proceeds to Step P25. If not, the process proceeds to Step P25 immediately.

  Next, in step P25, it is determined whether or not a paper width has been input to the paper width setting device 41. If yes, the setting value of the paper width setting device 41 is read in step P28 and overwritten in the current paper width storage memory M32. Thereafter, the process proceeds to step P29. If not, the process immediately proceeds to step P29.

  Next, in step P29, it is determined whether or not a folding specification has been input to the folding specification setting unit 42. If yes, the setting of the folding specification setting unit 42 is read in step P30 and overwritten in the folding specification storage memory M34. Then, the process proceeds to step P31, but if not, the process immediately proceeds to step P31.

  Next, in step P31, it is determined whether or not a rotational speed has been input to the rotational speed setter 43. If yes, the set value of the rotational speed setter 43 is read in step P32, and the set rotational speed storage memory M35. Is overwritten and the process returns to step P2. On the other hand, if no, the process returns to step P2.

  If NO in step P17, at least one of the routines in steps P33 to P43, the routines in steps P44 to P54, and the routines in steps P55 to P58 is executed in a non-sequential manner, and then the process returns to step 14.

  That is, when the waste paper signal from the auto paste device 36 or the print quality inspection device 37 is turned on in step P33, the count value is read from the current print number counting counter 34 in step P34, and the main printing stop position storage memory is read. After storing in M4, the final printing stop position (the current count value of the counter 34 for counting the number of printed sheets) is transmitted to the stacker / bundle control device 50 in step P35.

  Next, when the reception confirmation signal of the final printing stop position is transmitted from the stacker / bundleer control device 50 in step P36, it is determined in step P37 whether the output of the print number counting sensor 35 of the web rotary press is ON. To do.

  Next, if yes in step P37, the count value is read from the current print number counting counter 34 in step P38 and stored in the memory M3. If no, the process proceeds to step P40 described later.

  In step P39, the current count value of the counter 34 for counting the number of printed sheets is transmitted to the stacker / bundler control device 50. Then, in step P40, it is determined whether the waste paper signal is OFF.

  Next, if yes in step P40, the count value is read from the current print number counting counter 34 in step P41 and stored in the main printing restart position storage memory M5. If no, the process returns to step P37.

  Next, after sending the final printing restart position (the current count value of the counter 34 for counting the number of printed sheets) to the stacker / bundler control device 50 in step P42, the stacker / bundler control device 50 sets the final printing restart position in step P43. This routine ends when a reception confirmation signal is transmitted.

  On the other hand, when the regular paper switch 29 is turned OFF by the operator in step P44 due to a printing failure or the like, the count value is read from the current print number counting counter 34 and stored in the main printing stop position storage memory M4 in step P45. Thereafter, in step P46, the final printing stop position (current count value of the counter 34 for counting the number of printed sheets) is transmitted to the stacker / bundler control device 50.

  Next, when the reception confirmation signal of the final printing stop position is transmitted from the stacker / bundleer control device 50 in step P47, it is determined in step P48 whether or not the output of the print sheet count sensor 35 of the web rotary press is ON. To do.

  Next, if yes in step P48, the count value is read from the current print number counting counter 34 in step P49 and stored in the memory M3. If no, the process proceeds to step P51 described later.

  Next, after the count value of the current printing sheet count counter 34 is transmitted to the stacker / bundler control device 50 in step P50, the readjustment for printing is completed in the above-described step P51, and printing of the normal sheet is resumed. For example, it is determined whether the regular paper switch 29 is turned on by the operator.

  Next, if yes in step P51, the count value is read from the current printing sheet count counter 34 in step P52 and stored in the main printing restart position storage memory M5. If no, the process returns to step P48.

  In step P53, the final printing resumption position (the current count value of the counter 34 for counting the number of printed sheets) is transmitted to the stacker / bundler control device 50. Then, in step P54, the final printing resumption position is set from the stacker / bundler control device 50. This routine ends when a reception confirmation signal is transmitted.

  On the other hand, when the target print number setting unit 33 is re-input in step P55, the set value of the target print number setting unit 33 is read and stored in the target print number storage memory M2 in step P56.

  Next, after the target print number is transmitted to the stacker / bundler control device 50 in step P57, a reception confirmation signal for the target print number is transmitted from the stacker / bundler control device 50 in step P58, and this routine ends.

  With the above operation flow, each piece of information is transmitted to the stacker / bundler control device 50 in the order of the data indicating whether the picture is the same and the target print number → the final print start signal → the count value of the current print number counter 34. On the other hand, when the waste paper signal is turned ON and the normal paper switch 29 is turned OFF, the main printing stop position for the stacker / bundler control device 50 → the count value of the current printing sheet count counter 34 → the main printing restart position is set. Each information is transmitted in order, and when the target print number setting unit 33 is re-inputted, information on the re-input target print number is transmitted to the stacker / bundler control device 50.

  Next, in step P59 transferred from step P17 described above, an ink removal start command is transmitted to the ink film thickness preparation device 120, and then in step P60, the web paste standby of the new web roll 202 is sent to the auto paste device 36. A command to start paste preparation such as movement to a position or paper edge alignment between the old web roll 201 and the new web roll 202 is transmitted. Then, in step P61, 1 is sent to the operation status storage memory M36 of the auto paste device. Overwrite (active).

  Next, after reading the set rotational speed from the rotational speed setter 43 in step P62 and storing it in the previous rotational speed storage memory M37, whether or not a paste preparation completion signal is transmitted from the auto-paste device 36 in step P63. In step P64, 2 (stopped) is overwritten in step P64, and the process proceeds to step P65. If not, the process proceeds directly to step P65. To do.

  Next, after the previous rotational speed is read from the memory M37 in step P65, the rotational speed correction value at the time of deceleration is read from the memory M38 in step P66. Next, in Step P67, the current rotational speed is calculated by subtracting the rotational speed correction value at the time of deceleration from the previous rotational speed, and stored in the memory M39.

  Next, after reading the rotational speed at the time of blanket cleaning from the memory M80 at step P68, it is determined at step P69 whether or not the current rotational speed is smaller than the rotational speed at the time of blanket cleaning. After the rotational speed at the time of blanket cleaning is overwritten in the rotational speed storage memory M39, the current rotational speed is read from the memory M39 in step P70, and if no, the process immediately proceeds to step P70.

  Next, after overwriting the current rotational speed in the command rotational speed storage memory M81 in step P72, the command rotational speed is output to the driving motor driver 44 in step P73. Next, after the current rotational speed is overwritten in the previous rotational speed storage memory M37 in step P74, it is determined in step P75 whether an ink removal completion signal has been transmitted from the ink film thickness creating device 120.

  If yes in step P75, a print stop command is output to each of the printing units 102a to 102d in step P76, while if no, the process returns to step P63.

  Next, in step P77, the previous rotational speed is read from the memory M37, and in step P78, the rotational speed correction value during deceleration is read from the memory M38. Next, in step P79, the current rotational speed is calculated by subtracting the rotational speed correction value at the time of deceleration from the previous rotational speed, and stored in the memory M39.

  Next, after reading the rotational speed at the time of blanket cleaning from the memory M80 at step P80, it is determined at step P81 whether the current rotational speed is smaller than the rotational speed at the time of blanket cleaning. Is read from the memory M39, and the current rotational speed is overwritten in the command rotational speed storage memory M81 in step P83.

  Next, after outputting the command rotational speed to the driving motor driver 44 in step P84, the current rotational speed is overwritten in the previous rotational speed storage memory M37 in step P85, and the process returns to step P77.

  On the other hand, if yes in Step P81, the rotational speed at the time of blanket cleaning is read from the memory M80 at Step P86, and then the rotational speed at the time of blanket cleaning is overwritten in the current rotational speed storage memory M39 at Step P87.

  Next, after reading the current rotational speed from the memory M39 in step P88, the current rotational speed is overwritten in the command rotational speed storage memory M81 in step P89. Next, in step P90, the command rotational speed is output to the driving motor driver 44.

  Next, after a cleaning start command is transmitted to the blanket cleaning devices 121a and 121b in step P91, it is determined whether or not a paste preparation completion signal is transmitted from the auto paste device 36 in step P92. In P93, 2 (stopped) is overwritten in the operation status storage memory M36 of the auto-pasting apparatus, and the process proceeds to Step P94. On the other hand, if No, the process directly proceeds to Step P94.

  Next, in step P94, it is determined whether or not a cleaning completion signal is transmitted from the blanket cleaning devices 121a and 121b. If yes, whether or not a paste preparation completion signal is transmitted from the auto paste device 36 in step P95. On the other hand, if NO, the process returns to Step P92.

  Next, if yes in step P95, the operation state storage memory M36 of the auto paste device is overwritten with 2 (stopped) in step P96, and then the previous rotational speed is read from the memory M37 in step P97. If not, the process immediately proceeds to step P97.

  Next, after reading the rotational speed correction value during deceleration from the memory M38 in step P98, the current rotational speed is calculated by subtracting the rotational speed correction value during deceleration from the previous rotational speed in step P99, and the memory Store in M39.

  Next, in step P100, it is determined whether or not the current rotational speed <0. If yes, the current rotational speed storage memory M39 is overwritten with 0 in step P102, and then the current rotational speed is stored in the memory M39 in step P101. If the answer is no, the program immediately goes to Step P101.

  Next, after overwriting the current rotational speed in the command rotational speed storage memory M81 in step P103, the command rotational speed is output to the driving motor driver 44 in step P104. Next, in step P105, the current rotational speed is overwritten in the previous rotational speed storage memory M37.

  Next, after reading the contents of the operation status storage memory M36 of the auto paste device in step P106, it is determined in step P107 whether the contents of the operation status storage memory M36 of the auto paste device = 2. If yes, the process proceeds to step P108, which will be described later, whereas if no, the process returns to step P95.

  When a print completion signal is transmitted from the stacker / bundle control device 50 according to the above operation flow, an ink removal start command is transmitted to the ink film thickness creating device 120 which is an automatic switching device for job switching. A paste preparation start command is transmitted to the auto paste device 36, and then a cleaning start command is transmitted to the blanket cleaning devices 121a and 121b.

  Next, after the slow rotational speed is read from the memory M82 in step P108 described above, the slow rotational speed is overwritten in the current rotational speed storage memory M39 in step P109. Next, after reading the current rotational speed from the memory M39 in Step P110, the current rotational speed is overwritten in the command rotational speed storage memory M81 in Step P111.

  Next, after the command rotational speed is output to the driving motor driver 44 in Step P112, a paste start command is transmitted to the auto paste device 36 in Step P113. Next, in step P114, 1 (in operation) is overwritten in the operation state storage memory M36 of the auto paste device.

  Next, after the current paper width is read from the memory M32 in step P116, a preset start command and the current paper width are transmitted to the web preset device 122 in step P117.

  Next, in step P118, 1 (in operation) is overwritten in the operation status storage memory M83 of the web preset device, and in step P119, a pre-inking preparation start command (point key control device (PQC) is sent to the ink film thickness creating device 120. ) Send a preset). Next, in step P120, 1 (in operation) is overwritten in the operation state storage memory M84 of the ink film thickness producing device.

  Next, in step P121, it is determined whether or not a paste completion command has been transmitted from the auto paste device 36. If yes, 2 (stopped) is stored in the operation status storage memory M36 of the auto paste device in step P122. On the other hand, if not, the process proceeds to Step P125 described later.

  Next, it is determined whether or not a preset completion signal has been transmitted from the web preset device 122 in step P125 described above. If yes, the operation status storage memory M83 of the web preset device is set to 2 (stopped) in step P126. ) Is overwritten and the process proceeds to step P127, and if no, the process immediately proceeds to step P127.

  Next, in step P127, it is determined whether or not a pre-inking preparation completion signal is transmitted from the ink film thickness creating device 120. If yes, in step P128, the ink film thickness creating device stores the operation status storage memory M84. 2 (stopped) is overwritten and the process proceeds to step P129. If not, the process immediately proceeds to step P129.

  Next, after reading the contents of the operation status storage memory M36 of the auto paste device in step P129, it is determined in step P130 whether the contents of the operation status storage memory M36 of the auto paste device = 2. If yes, read the contents of the operation status storage memory M83 of the web preset device in Step P131, and then go to Step P132. If not, return to Step P121.

  Next, in step P132, it is determined whether or not the content of the operation status storage memory of the web preset device = 2. If yes, the process proceeds to step P133. If not, the process returns to step P121.

  Next, in step P133, it is determined whether or not a pre-inking preparation completion signal has been transmitted from the ink film thickness creating device 120. If yes, in step P134, the ink film thickness creating device operation status storage memory M84 is determined. After overwriting 2 (stopped), the process proceeds to step P137. If not, the process proceeds to step P137.

  Next, after an operation start command is transmitted to the dancer devices 123a and 123b in step P137, a plate change start command is transmitted to the automatic plate change devices 124a and 124b in step P138.

  Next, in step P139, it is determined whether or not a pre-inking preparation completion signal has been transmitted from the ink film thickness creating device 120. If yes, 2 is stored in the operation state storage memory M84 of the ink film thickness creating device in step P140. After overwriting (stopped), the process proceeds to step P141. If not, the process immediately proceeds to step P141.

  Next, in step P141, it is determined whether or not a plate change completion signal is transmitted from the automatic plate changers 124a and 124b. If yes, the slow rotational speed is read from the memory M82 in step P157. If not, the process returns to Step P139.

  Next, after overwriting the slow rotational speed in the current rotational speed storage memory M39 in step P143, the current rotational speed is read from the memory M39 in step P144. Next, after overwriting the current rotational speed in the command rotational speed storage memory M81 in step P145, the command rotational speed is output to the driving motor driver 44 in step P146.

  Next, in step P147, a paper feed stop command is transmitted to the auto paste device 36 and the infeed device 125, and in step P148, whether or not a pre-inking preparation completion signal is transmitted from the ink film thickness creating device 120 is determined. to decide.

  Next, if yes in Step P148, the operation state storage memory M84 of the ink film thickness creating apparatus is overwritten with 2 (stopped) in Step P149, and then the process proceeds to Step P150. The process proceeds to step P150.

  Next, in step P150, it is determined whether or not a paper slack removal completion signal is transmitted from the dancer devices 123a and 123b. If yes, an operation end command is transmitted to the dancer devices 123a and 123b in step P151. If not, the process returns to Step P148.

  Next, in step P152, it is determined whether or not a pre-inking preparation completion signal has been transmitted from the ink film thickness creating device 120. If yes, 2 is stored in the operation status storage memory M84 of the ink film thickness creating device in step P153. After overwriting (stopped), the process proceeds to step P154. If not, the process immediately proceeds to step P154.

  Next, after the folding specification is read from the memory M34 in step P154, the folding specification switching start command and folding specification are transmitted to the folding specification switching device 126 in step P155.

  Next, in step P156, it is determined whether or not a pre-inking preparation completion signal has been transmitted from the ink film thickness creating device 120. If yes, 2 is stored in the operation status storage memory M84 of the ink film thickness creating device in step P157. After overwriting (stopped), the process proceeds to step P158. If not, the process proceeds to step P158 immediately.

  Next, in step P158, it is determined whether or not a folding specification switching completion signal is transmitted from the folding specification switching device 126. If yes, the process proceeds to step P159, which will be described later. If not, the process returns to step P156. .

  Next, in step P159, it is determined whether or not a pre-inking preparation completion signal is transmitted from the ink film thickness creating device 120. If yes, in step P160, the ink film thickness creating device stores the operation status storage memory M84. After overwriting 2 (stopped), the process proceeds to step P161. If not, the process immediately proceeds to step P161.

  When the print completion signal is transmitted from the stacker / bundleer control device 50 according to the above operation flow, the paste start command to the auto paste device 36 → the web preset device 122 is continued following the job switching start command described above. It is transmitted in the order of preset start command → operation start command to dancer devices 123a, 123b → print plate change command to automatic plate change devices 124a, 124b → fold specification switching start command to folding specification switch device 126.

  Next, after the temperature rising start command is transmitted to the drying apparatus 103 in Step P161, it is determined whether or not a pre-inking preparation completion signal is transmitted from the ink film thickness creating apparatus 120 in Step P162. In step P163, 2 (stopped) is overwritten in the operation state storage memory M84 of the ink film thickness creating apparatus, and then the process proceeds to step P164. If not, the process immediately proceeds to step P208.

  Next, it is determined whether or not a temperature raising completion signal is transmitted from the drying apparatus 103 in step P164. If yes, whether or not a pre-inking preparation completion signal is transmitted from the ink film thickness creating apparatus 120 in step P165. If NO, the process returns to Step P162.

  Next, if yes in step P165, the operation state storage memory M84 of the ink film thickness creating apparatus is overwritten with 2 (stopped) in step P166, and then the process proceeds to step P167. Control goes to step P167.

  Next, after reading the contents of the operation status storage memory M84 of the ink film thickness creation device in step P167, it is determined in step P168 whether or not the contents of the operation status storage memory M84 of the ink film thickness creation device = 2. If YES, the slow rotational speed is read from the memory M82 in step P169. If NO, the process returns to step P165.

  Next, after overwriting the slow rotational speed in the previous rotational speed storage memory M37 in step P170, the previous rotational speed is read from the memory M37 in step P171. Next, in step P172, the rotational speed correction value at the time of acceleration is read from the memory M89.

  Next, in step P173, the current rotational speed is calculated by adding the rotational speed correction value at the time of acceleration to the previous rotational speed and stored in the memory M39. Then, in step P174, the current rotational speed is stored in the command rotational speed storage memory M81. Override the rotation speed of. Next, in step P175, the command rotational speed is output to the driving motor driver 44.

  Next, in step P176, the current rotational speed is read from the memory M39, and in step P177, the rotational speed at the start of pre-inking is read from the memory M90. Next, in step P178, it is determined whether or not the current rotational speed> the rotational speed at the start of pre-inking. If yes, the process proceeds to step P180 described later. If not, the previous rotational speed is stored in step P179. The memory M37 is overwritten with the current rotation speed, and the process returns to Step P171.

  Next, after the pre-inking start command is transmitted to the ink film thickness creating device 120 in Step P180 described above, the previous rotation speed is read from the memory M37 in Step P181. Next, after the rotational speed correction value at the time of acceleration is read from the memory M89 at Step P182, the current rotational speed is calculated by adding the rotational speed correction value at the time of acceleration to the previous rotational speed at Step P183, Store in the memory M39.

  Next, after overwriting the current rotational speed in the command rotational speed storage memory M81 in step P184, the command rotational speed is output to the driving motor driver 44 in step P185. Next, in step P186, the current rotational speed is overwritten in the previous rotational speed storage memory M37.

  Next, in step P187, it is determined whether or not a pre-inking completion signal is transmitted from the ink film thickness creating device 120. If yes, a print start command is output to each of the printing units 102a to 102d in step P188. If not, the process returns to Step P181.

  Next, in step P189, the previous rotational speed is read from the memory M37, and in step P190, the rotational speed correction value at the time of acceleration is read from the memory M89. Next, in step P191, the current rotational speed is calculated by adding the rotational speed correction value at the time of acceleration to the previous rotational speed, and stored in the memory M39.

  Next, in step P192, the set rotational speed is read from the rotational speed setter 43 and stored in the memory M35. Then, in step P193, it is determined whether or not the current rotational speed is smaller than the set rotational speed. If yes, in step P194. While overwriting the current rotational speed in the command rotational speed storage memory M81, if not, the process proceeds to Step P197 described later.

  Next, in step P195, the command rotational speed is output to the driving motor driver 44, and in step P196, the current rotational speed is overwritten in the previous rotational speed storage memory M37, and the process returns to step P189.

  Next, in step P197 described above, the set rotational speed is read from the rotational speed setter 43 and stored in the memory M35. Then, in step P198, the current rotational speed storage memory M39 is overwritten with the set rotational speed.

  Next, after reading the current rotational speed from the memory M39 in Step P199, the current rotational speed is overwritten in the command rotational speed storage memory M81 in Step P200. Next, in step P201, the command rotational speed is output to the driving motor driver 44, and the process returns to step P5.

  When a print completion signal is transmitted from the stacker / bundler control device 50 according to the above operation flow, the temperature increase start command to the drying device 103 → the ink film thickness creation device 120 is transferred following the job switching start command described above. The pre-inking start commands are transmitted in this order, and then a print start command is output to each of the printing units 102a to 102d.

  On the other hand, the control operation of the stacker / bundler control device 50 will be described in detail with reference to the operation flowcharts of FIGS. 7A and 7B, FIGS.

  First, after initialization processing in step P1, data on whether or not the same pattern and the target number of prints are transmitted from the control device 10 of the web rotary press in step P2, and then the control device of the web rotary press in step P3. The data indicating whether or not the image is the same and the target print number are received from 10 and stored in the memory M40 and the memory M41.

  Next, in step P4, data indicating whether or not the images are the same and a reception confirmation signal for the target number of prints are transmitted to the control device 10 of the web rotary press. Then, in step P5, the main printing start signal is transmitted from the control device 10 of the web rotary press. Is transmitted, in step P6, a reception confirmation signal for the final printing start signal is transmitted to the control device 10 of the web rotary press.

  Next, in step P7, a reset signal and an enable signal are output to the current sheet count counters 62A and 62B on the A side and B side, and then in step P8, the current sheet count on the A side and B side is counted. The output of the reset signal to the counters 62A and 62B is stopped.

  Next, after overwriting the count value M of the memory M42 with 0 in step P9, the count value N of the memory M43 is overwritten with 0 in step P10.

  Next, in step P11, it is determined whether or not the final printing stop position has been transmitted from the control device 10 of the web rotary press. If yes, the count value M is read from the memory M42 in step P12. For example, the process proceeds to Step P16 described later.

  Next, in step P13, 1 is added to the count value M of the memory M42 and overwriting is performed. Then, in step P14, the main printing stop position is received from the control device 10 of the web rotary press, and the main printing stop position storage memory M44. At the Mth address position.

  Next, after the reception confirmation signal of the final printing stop position is transmitted to the control device 10 of the web rotary press in step P15, is the final printing restart position transmitted from the control device 10 of the web rotary printing press in step P16 described above? Judge whether or not.

  Next, if yes in step P16, the count value N is read from the memory M43 in step P17. If no, the process proceeds to step P21 described later. Next, in step P18, 1 is added to the count value N of the memory M43 and overwritten.

  Next, in step P19, the final printing restart position is received from the control device 10 of the web rotary press and stored in the Nth address position of the main printing restart position storage memory M45. A reception confirmation signal at the final printing restart position is transmitted to the control device 10.

  Next, in step P21, it is determined whether or not the target number of prints has been transmitted from the control device 10 of the web rotary press. If yes, the target print number is determined from the control device 10 of the web rotary press in step P22. After receiving and storing it in the memory M41, in step P23, a reception confirmation signal for the target print number is transmitted to the control device 10 of the web rotary press, and the process proceeds to step P24 described later. On the other hand, if the result is NO in step 21, the process immediately proceeds to step P24.

  According to the above operation flow, after receiving the data indicating whether or not the same image and the target number of prints are received from the control device 10 of the web rotary press, the main printing start signal is received, and the main printing is performed from the control device 10 of the web rotary press. When the stop position and the final printing restart position are received, the positions are stored in the address positions corresponding to the received order (M or N). When the target print number is received, it is stored.

  Next, in step 24, it is determined whether or not the current count value of the counter 34 for counting the number of printed sheets has been transmitted from the control device 10 of the web rotary press, and if yes, in step P25, the web rotary press. The count value of the current print sheet count counter 34 is received from the control device 10 and stored in the print sheet storage memory M46 of the current web rotary press.

  Next, after overwriting 1 in the count value MM of the memory M47 in step P26, the count value MM is read from the memory M47 in step P27. Next, the count value M is read from the memory M42 in step P28.

  Next, in step P29, it is determined whether or not the count value MM> the count value M. If yes, the process proceeds to step P46 described later. If no, the count value MM is read from the memory M47 in step P30.

  Next, in step P31, the MMth final printing stop position is read from the MMth address position in the main printing stop position storage memory M44 and stored in the memory M48. Then, in step P32, the rejection device 64A on the A side from the memory M49 is read. (The number of sheets from the web-fed rotary printing press to the A-side reject device 64A).

  Next, in step P33, the number of sheets up to the A-side reject device 64A is added to the MM-th final printing stop position to calculate the A-side MM-th reject start position, which is stored in the memory M50, and then in step P34. The current number of printed sheets of the web rotary press is read from the memory M46.

  Next, in step P35, it is determined whether or not the MM-th reject start position on the A side is the current number of pages printed by the web rotary press. If yes, a reject signal is output to the A-side reject device 64A in step P36. Then, the process proceeds to step P37, which will be described later. On the other hand, if no, the process proceeds to step P37.

  Next, after reading the count value MM from the memory M47 in step P37 described above, in step P38, the MMth final printing stop position is read from the MMth address position of the final printing stop position storage memory M44, and the memory M48. To remember.

  Next, after reading the number of sheets from the memory M51 to the B-side reject device 64B (the number of sheets from the web rotary press to the B-side reject device 64B) at Step P39, at Step P40, the MMth final printing stop position Is added to the B-side reject device 64B, and the MM-th reject start position on the B side is calculated and stored in the memory M52.

  Next, in step P41, the current number of pages printed on the web rotary press is read from the memory M46, and in step P42, whether or not the MM-th reject start position on the B side is the current number of pages printed on the web rotary press. to decide.

  Next, if yes in step P42, a reject signal is output to the B-side reject device 64B in step P43, and the process proceeds to step P44 described later, whereas if no, the process immediately proceeds to step 44.

  Next, after reading the count value MM from the memory M47 in step P44 described above, 1 is added to the count value MM in the memory M47 and overwritten in step P45, and the process returns to step P27.

  Next, after the count value NN of the memory M53 is overwritten with 1 in step P46 described above, the count value NN is read from the memory M53 in step P47. Next, in step P48, the count value N is read from the memory M43.

  Next, in step P49, it is determined whether or not the count value NN> the count value N. If yes, the process proceeds to step P66 described later. If no, the count value NN is read from the memory M53 in step P50.

  Next, in step P51, the NNth final printing restart position is read from the NNth address position of the main printing restart position storage memory M45 and stored in the memory M54. Then, in step P52, the A side reject device 64A is sent from the memory M49. Read up to.

  Next, in step P53, the number of sheets up to the A-side rejection device 64A is added to the NN-th final printing restart position to calculate the NN-th rejection completion position on the A side, and the result is stored in the memory M55. The current number of printed sheets of the web rotary press is read from the memory M46.

  Next, in step P55, it is determined whether or not the NNth reject completion position on the A side = the current number of printed pages of the web rotary press. If yes, a reject signal to the A side reject device 64A is determined in step P56. The output is stopped and the process proceeds to Step P57, which will be described later. On the other hand, if not, the process proceeds to Step P57.

  Next, after reading the count value NN from the memory M53 in the above-described step P57, in step P58, the NNth final printing restart position is read from the NNth address position of the final printing restart position storage memory M45, and the memory M54 is read. To remember.

  Next, in step P59, the number of sheets from the memory M51 to the B-side reject device 64B is read, and in step P60, the number of sheets up to the B-side reject device 64B is added to the NNth final printing restart position. Is calculated and stored in the memory M56.

  Next, in step P61, the current number of pages printed on the web rotary press is read from the memory M46, and in step P62, whether or not the NNth reject completion position on the B side is the current number of pages printed on the web rotary press. to decide.

  Next, if yes in step P62, the output of the reject signal to the B-side reject device 64B is stopped in step P63, and the process proceeds to step P64 described later. If not, the process proceeds to step 64 immediately. To do.

  Next, after reading the count value NN from the memory M53 in the above-described Step P64, 1 is added to the count value NN in the memory M53 and overwritten in Step P65, and the process returns to Step P47.

  With the above operation flow, the A-side and B-side reject devices 64A and 64B are operated corresponding to the main printing stop position and the main printing resuming position, and the waste paper (scrap paper) can be reliably removed.

  Next, after overwriting 1 in the count value MM of the memory M47 in step P66 described above, the count value MM is read from the memory M47 in step P67. Next, in step P68, the count value M is read from the memory M42.

  Next, in step P69, it is determined whether or not the count value MM> the count value M. If yes, the process proceeds to step P86 described later. If no, the count value MM is read from the memory M47 in step P70.

  Next, in step P71, the MMth final printing stop position is read from the MMth address position in the main printing stop position storage memory M44 and stored in the memory M48, and then in step P72, the small bundle portion on the A side from the memory M57. The number of sheets up to the paper supply confirmation sensor 63A (number of sheets from the web rotary printing press to the A-side small bundle paper supply confirmation sensor 63A) is read.

  Next, in step P73, the number of sheets up to the A-side small bundle paper supply confirmation sensor 63A is added to the MM-th final printing stop position to calculate the A-side MM-th count stop position and stored in the memory M58. After that, in step P74, the current number of printed sheets of the web rotary press is read from the memory M46.

  Next, in step P75, it is determined whether or not the MMth count stop position on the A side = the current number of pages printed on the web rotary press. If yes, the current counter for counting the current number of normal sheets on the A side is determined in step P76. The output of the enable signal to 62A is stopped and the process proceeds to Step P77, which will be described later. On the other hand, if not, the process proceeds to Step P77.

  Next, after reading the count value MM from the memory M47 in step P77 described above, in step P78, the MMth final printing stop position is read from the MMth address position of the final printing stop position storage memory M44, and the memory M48. To remember.

  Next, in step P79, the number of sheets from the memory M59 to the B-side small bundle paper supply confirmation sensor 63B (the number of sheets from the web rotary press to the B-side small bundle paper supply confirmation sensor 63B) is read. Thereafter, in step P80, the number of sheets up to the B-side small bundle paper supply confirmation sensor 63B is added to the MM-th final printing stop position, and the B-side MM-th count stop position is calculated and stored in the memory M60. To do.

  Next, in step P81, the current number of pages printed on the web rotary press is read from the memory M46, and in step P82, whether or not the MMth count stop position on the B side is the current number of pages printed on the web rotary press. to decide.

  Next, if yes in step P82, in step P83, the output of the enable signal to the current normal sheet count counter 62B on the B side is stopped and the process proceeds to step P84 described later. Then, the process proceeds to step 84.

  Next, after reading the count value MM from the memory M47 in step P84 described above, 1 is added to the count value MM in the memory M47 and overwritten in step P85, and the process returns to step P67.

  Next, after the count value NN of the memory M53 is overwritten with 1 in step P86 described above, the count value NN is read from the memory M53 in step P87. Next, in step P88, the count value N is read from the memory M43.

  Next, in step P89, it is determined whether or not the count value NN> the count value N. If yes, the process proceeds to step P106 described later. If no, the count value NN is read from the memory M53 in step P90.

  Next, in step P91, the NNth final printing restart position is read from the NNth address position in the main printing restart position storage memory M45 and stored in the memory M54. Then, in step P92, the small bundle portion on the A side from the memory M57. The number of sheets up to the paper supply confirmation sensor 63A is read.

  Next, in step P93, the number of sheets up to the A side small bundle paper supply confirmation sensor 63A is added to the NNth final printing restart position to calculate the NNth count restart position on the A side and stored in the memory M61. After that, in step P94, the current number of printed sheets of the web rotary press is read from the memory M46.

  Next, in step P95, it is determined whether or not the NNth count restart position on the A side = the current number of pages printed by the web rotary press, and if yes, the current counter for counting the number of normal sheets on the A side is determined in step P96. While an enable signal is output to 62A and the process proceeds to Step P97 described later, if not, the process immediately proceeds to Step P97.

  Next, after reading the count value NN from the memory M53 in the above-described step P97, in step P98, the NNth final printing restart position is read from the NNth address position of the final printing restart position storage memory M45, and the memory M54 is read. To remember.

  Next, after reading the number of sheets from the memory M59 to the B-side small bundle paper supply confirmation sensor 63B in step P99, in step P100, the B-side small bundle paper supply confirmation is performed at the NN-th actual printing restart position. The number of sensors up to the sensor 63B is added, and the NNth count restart position on the B side is calculated and stored in the memory M62.

  Next, in step P101, the current number of pages printed on the web rotary press is read from the memory M46, and in step P102, whether or not the NNth count restart position on the B side is the current number of pages printed on the web rotary press. to decide.

  Next, if yes in step P102, an enable signal is output to the current normal sheet count counter 62B on the B side in step P103, and the process proceeds to step P104 described later. 104.

  Next, after reading the count value NN from the memory M53 at Step P104 described above, 1 is added to the count value NN of the memory M53 and overwritten at Step P105, and the process returns to Step P87.

  According to the operation flow described above, the current normal sheet number counting counters 62A and 62B on the A side and the B side are operated corresponding to the main printing stop position and the main printing resuming position, and the number of normal sheets can be accurately counted.

  Next, after the data on whether or not the same picture is read from the memory M40 in Step P106 described above, it is determined whether or not the data on whether or not the same picture is equal to 1 in Step P107. The count value is read from the current normal sheet count counter 62A and stored in the memory M63. If not, the process proceeds to Step P115 described later.

  Next, in step P109, the count value is read from the current normal sheet number counter 62B on the B side and stored in the memory M64. Then, in step P110, the count value of the current normal sheet number count counter 62A on the A side is set. The count value of the current normal sheet count counter 62B on the B side is added to calculate the current total correct sheet count and store it in the memory M65.

  Next, after reading the target print number from the memory M41 in step P111, the target total print number is calculated by multiplying the target print number by 2 in step P112 and stored in the memory M66.

  Next, in step P113, it is determined whether or not the current total number of regular sheets ≧ target total number of printed sheets. If yes, a print completion signal is transmitted to the control device 10 of the web rotary press in step P114, and the process proceeds to step P2. On the other hand, if no, the process returns to Step P11.

  Next, in step P115, the count value is read from the A-side current sheet number counting counter 62A and stored in the memory M63. Then, in step P116, the current sheet number counting counter 62B on the B side counts. The value is read and stored in the memory M64.

  Next, in step P117, it is determined whether or not the count value of the current paper sheet count counter on the A side ≦ the count value of the current paper sheet count counter on the B side. While reading the target print number from M41, if not, the process proceeds to Step P121 described later.

  Next, in step P119, it is determined whether or not the count value of the current sheet count counter on the A side is equal to the target print number. If yes, a print completion signal is sent to the controller 10 of the web rotary press in step P120. Is transmitted and the process returns to Step P2, while if NO, the process returns to Step P11.

  Next, after reading the target print number from the memory M41 in step P121 described above, it is determined in step P122 whether or not the count value of the current normal sheet number counter on the B side = target print number. If there is, a print completion signal is transmitted to the control device 10 of the web rotary press in step P123 and the process returns to step P2, while if no, the process returns to step P11.

  With the above operation flow, in the case of the same pattern, when the total number of sheets collected by the A-side and B-side stacker / bundle devices 115A and 115B reaches the required number or more, printing to the web rotary press 100 is completed. On the other hand, if the signals are output but the same pattern is not received, a print completion signal is sent to the web rotary press 100 when the number of sheets collected by the smaller stacker / bundle apparatus 115A or 115B reaches the required number. Is output.

  In this way, in this embodiment, the web-fed rotary printing machine cuts the web with the slitter 109 in the left-right direction, and then discharges the signatures cut in the front-rear direction to the A-side and B-side stacker and bundlers 115A and 115B. In 100, the number of sheets is counted by the stacker / bundler control device 50, and in the case of the same pattern, the total number of sheets collected by the A side and B side stacker / bundle devices 115A and 115B is more than the required number. In the case where the print completion signal is output to the web rotary press 100, the number of sheets collected by the stacker / bundle apparatus 115A or 115B with the smaller number of collected sheets reaches the required number. Then, a print completion signal is output to the web rotary press 100. Note that the determination of the completion of printing in the case of the same pattern is (current total number of printed sheets ≧ target total number of printed sheets). In this case, the total number of printed sheets is always an even number. In some cases, the count value of the current counter for counting the number of normal sheets is an even number and the other is an odd number. In this case, printing is completed when (current total number of printed sheets = target total number of printed sheets + 1). Because it becomes.

  Further, each automatic switching device for setting the setting of the web rotary press in accordance with the next printed matter is automatically operated in response to the print completion signal.

  As a result, the burden on the operator can be reduced by automation, the web rotary press can be stopped as quickly as possible, and the operating rate can be improved by eliminating waste of printing materials as much as possible.

  FIGS. 10A and 10B are block diagrams of a control apparatus for a web rotary printing press showing Embodiment 2 of the present invention, FIGS. 11A and 11B are block diagrams of an A-side and B-side stacker and bundler control apparatus, and FIGS. 12D is an operation flow diagram of the control device of the web rotary press, FIGS. 13A and 13B are operation flow diagrams of the control device of the web rotary press, and FIGS. 14A and 14B are operation flow diagrams of the control device of the web rotary press, 15A and 15B are operation flowcharts of the control device of the web rotary press, FIGS. 16A to 16D are operation flow diagrams of the control device of the web rotary printing press, and FIGS. 17A to 17D are diagrams of the control device of the web rotary press. FIG. 18A to FIG. 18C are operation flow diagrams of the control device of the web rotary press, and FIG. 19A and FIG. 19B are the A side and B side stacker bands. Operational flowchart of-controlled device, FIGS. 20A to 20D shows an operational flowchart of the stacker bundler control apparatus A side and B side.

  In the first embodiment, the stacker / bundler control device 50 counts the number of sheets, and when the number of sheets reaches the required number, instead of outputting a print completion signal to the web rotary press 100, This is an example in which the number of sheets is counted on the web rotary press 100 side based on the information on the number of sheets on the B side stacker / bundle device 115A, 115B, and when the number of sheets reaches the required number, printing is terminated by itself. . The other configuration is the same as that of the first embodiment, and therefore, redundant description will be omitted with reference to FIGS. 32 to 41, FIGS. 42A and 42B, and FIG.

  That is, as shown in FIG. 10A and FIG. 10B, the control device 10 of the web rotary printing press is configured such that the CPU 11, the ROM 12, the RAM 13, the input / output devices 15a to 15m, and the interface 16 are all connected by a BUS (bus). .

  Also, the BUS (bus line) includes a data storage memory M1, a target print number storage memory M2, a count value storage memory M3 of a current print number count counter, and a main printing stop position storage memory. M4 and the main printing restart position storage memory M5 are connected.

  In the BUS (bus line), the count value C storage memory M6, the A-side current sheet number storage memory M7, the B-side current sheet number storage memory M8, and the current total sheet number storage are stored. The memory M9 for memory and the memory M10 for storing the target print number are connected.

  Further, the current paper width storage memory M32, the folding specification storage memory M34, the set rotational speed storage memory M35, the operation state storage memory M36 of the auto-paste device, and the previous rotational speed storage are included in the BUS (bus). The memory M37, the memory for storing the rotational speed correction value M38 during deceleration, and the memory for storing the current rotational speed M39 are connected.

  Further, the BUS (bus bar) includes a rotational speed storage memory M80, a command rotational speed storage memory M81, a slow rotational speed storage memory M82, an operation status storage memory M83 of the web preset device, and an ink for blanket cleaning. An operation state storage memory M84 of the film thickness creation device, a rotational speed correction value storage memory M89 at the time of acceleration, and a rotational speed storage memory M90 at the start of pre-inking are connected.

  The input / output device 15a includes an identical picture setting switch 26, a setting completion switch 27, a print start switch 28, a regular paper switch (self-holding switch) 29, an input device 30 such as a keyboard, and a display 31 such as a CRT or display. An output device 32 such as a printer or a floppy disk (registered trademark) drive is connected.

  A target print number setting device 33 is connected to the input / output device 15b. A paper width setting device 41 is connected to the input / output device 15c. A folding specification setting device 42 is connected to the input / output device 15d. A rotation speed setting unit 43 is connected to the input / output device 15e.

  The input / output device 15f is connected with a sensor 35 for counting the number of printed sheets of a web rotary press. The input / output device 15g is connected with a counter 34 for counting the current number of printed sheets, and the counter 34 for counting the number of currently printed sheets is connected with a sensor 35 for counting the number of printed sheets of a web rotary press. The input / output device 15h is connected to a counter 34 for counting the current number of printed sheets, to which a reset signal and an enable signal are output.

  The auto paste device 36 and the print quality inspection device 37 described above are connected to the input / output device 15i, from which a waste paper signal is input.

  A driving motor 45 is connected to the input / output device 15j via a D / A converter 17 and a driving motor driver 44. A driving motor rotary encoder 46 connected to the driving motor 45 is connected to the driving motor driver 44.

  The input / output device 15m includes a first color printing unit (operation panel) 102a, a second color printing unit (operation panel) 102b, a third color printing unit (operation panel) 102c, and a fourth color printing unit (operation panel) 102d. Is connected.

  The interface 16 includes an A side stacker / bundler control device 50A, a B side stacker / bundler control device 50B, an ink film thickness preparation device 120, an auto paste device 36, a blanket cleaning device 121a, 121b, a web preset device 122, and a dancer. The devices 123a and 123b, the automatic plate changing devices 124a and 124b, the infeed device 125, the folding specification switching device 126, and the drying device 103 are connected.

  On the other hand, as shown in FIGS. 11A and 11B, the stacker / bundler control devices 50A and 50B are configured such that the CPU 51, the ROM 52, the RAM 53, the input / output devices 54 to 57, and the interface 58 are all connected by a BUS (bus). .

  The BUS (bus line) includes a data storage memory M40, a target print number storage memory M41, a count value M storage memory M42, a count value N storage memory M43, and a final printing stop position storage. A memory M44, a full-printing resume position storage memory M45, and a current print number storage memory M46 of the web rotary press are connected.

  Further, the BUS (bus line) includes a count value MM storage memory M47, an MMth final printing stop position storage memory M48, a number storage memory M67 up to the reject device, and an MMth rejection start position storage memory M68. The count value NN storage memory M53 and the NNth final printing restart position storage memory M54 are connected.

  Further, the BUS (bus) includes the NNth reject completion position storage memory M69, the number of sheets storage memory M70 up to the small bundle paper supply confirmation sensor, the MMth count stop position storage memory M71, and the NNth count. The restart position storage memory M72 and the current normal sheet count storage memory M73 are connected.

  An input device 59 such as a keyboard, a display device 60 such as a CRT or a display, and an output device 61 such as a printer or a floppy disk (registered trademark) drive are connected to the input / output device 54.

  A current sheet count counter 62 is connected to the input / output device 55. The current sheet count counter 62 is connected to a small bundle paper supply check sensor 63 and web rotary printing via an AND circuit. A printer 35 count sensor 35 is connected.

  The input / output device 57 is connected to the reject device 64 described above, and a reject signal is output thereto.

  The interface 58 is connected to the control device 10 of the web rotary press.

  Control operations of the control device 10 of the web rotary press having the above-described configuration are shown in FIGS. 12A to 12D, 13A and 13B, 14A and 14B, 15A and 15B, 16A to 16D, and 17A to 17A. This will be described in detail with reference to the operation flowcharts of FIG. 17D and FIGS.

  First, after initialization in step P1, it is determined in step P2 whether or not the setting completion switch 27 is ON. If yes, the print start switch 28 is turned ON in step P3 and printing is started in step P4. .

  Next, in step P5, a reset signal and an enable signal are output to the current print number counting counter 34. Then, in step P6, the output of the reset signal to the current print number counting counter 34 is stopped.

  Next, in step P7, data indicating whether or not the picture is the same is read from the memory M1, and then in step P8, the target print number is read from the memory M2. Next, in step P9, the data indicating whether or not the images are the same and the target print number are transmitted to the A-side and B-side stacker and bundler control devices 50A and 50B.

  Next, in step P10, the A-side and B-side stacker / bundler control devices 50A and 50B transmit the data indicating whether or not they have the same pattern and the target print number reception confirmation signal. Then, in step P12, a final printing start signal is transmitted to the A side and B side stacker and bundler control devices 50A and 50B. Next, when a reception confirmation signal of the main printing start signal is transmitted from the A side and B side stacker / bundler control devices 50A and 50B in step P13, the output of the print number counting sensor 35 of the web rotary press in step P14. Determine whether is ON.

  Next, if yes in step P14, the count value is read from the current print number counting counter 34 in step P15 and stored in the memory M3. If no, the process proceeds to step P32 described later.

  In step P16, the current count value of the counter 34 for counting the number of printed sheets is transmitted to the A-side and B-side stacker / bundleer control devices 50A and 50B, and the process proceeds to step P56 described later.

  If NO in step P2, it is determined in step P17 whether or not the same picture setting switch 26 is ON. If yes, the contents of the data storage memory M1 are read in step P18 to determine whether or not the same picture is set. If not, the process proceeds to Step P22 described later.

  Next, in step P19, it is determined whether or not the content of the data storage memory for the same picture = 0. If yes, 1 (identical) is overwritten in the data storage memory M1 for the same picture in step P20. Then, the process proceeds to step P22. On the other hand, if the result is NO, the data storage memory M1 indicating whether the picture is the same is overwritten with 0 (different) and the process proceeds to step P22.

  Next, it is determined whether or not the target print number setting device 33 has been input to the target print number setting device 33 in step P22 described above. If yes, the setting value of the target print number setting device 33 is read and stored in step P23. After overwriting the memory M2, the process proceeds to step P24, while if not, the process proceeds to step P24 immediately.

  Next, in step P24, it is determined whether or not a paper width has been input to the paper width setting device 41. If yes, the setting value in the paper width setting device 41 is read in step P27 and overwritten in the current paper width storage memory M32. Thereafter, the process proceeds to step P28, and if not, the process immediately proceeds to step P28.

  Next, in step P28, it is determined whether or not a folding specification has been input to the folding specification setting unit 42. If yes, the setting of the folding specification setting unit 42 is read in step P29 and overwritten in the folding specification storage memory M34. Then, the process proceeds to step P30, while if not, the process proceeds to step P30 immediately.

  Next, in step P30, it is determined whether or not a rotation speed has been input to the rotation speed setting unit 43. Is overwritten and the process returns to step P2. On the other hand, if no, the process returns to step P2.

  If NO in step P14, it is determined in step P32 whether the waste paper signal from the auto paste device 36 or the print quality inspection device 37 has been turned ON. The count value is read from the count counter 34 and stored in the main printing stop position storage memory M4. On the other hand, if not, the process proceeds to Step P43 described later.

  Next, after sending the final printing stop position (current count value of the counter for counting the number of printed sheets 34) to the A-side and B-side stacker / bundler control devices 50A and 50B in step P34, the A side and B in step P35. When the reception confirmation signal of the final printing stop position is transmitted from the side stacker / bundler control device 50A, 50B, it is determined in step P36 whether the output of the print number counting sensor 35 of the web rotary press is ON.

  Next, if yes in step P36, the count value is read from the current print number counting counter 34 in step P37 and stored in the memory M3. If no, the process proceeds to step P39 described later.

  Next, in step P38, the current count value of the counter 34 for counting the number of printed sheets is transmitted to the A-side and B-side stacker / bundler control devices 50A and 50B, and then the process proceeds to step P84 described later.

  Next, it is determined whether or not the waste paper signal has been turned off in step P39 described above, and if yes, the count value is read from the current printing sheet count counter 34 in step P40 and stored in the main printing restart position storage memory M5. On the other hand, if not, the process returns to Step P36.

  Next, after the printing restart position (the current count value of the counter 34 for counting the number of printed sheets) is transmitted to the A-side and B-side stacker / bundler control devices 50A and 50B at step P41, the A side and B The reception confirmation signal for the final printing resumption position is transmitted from the stacker / bundler control devices 50A and 50B on the side, and the process proceeds to step P43 described above.

  Next, in step P43, it is determined whether or not the regular paper switch 29 is turned off. If yes, the count value is read from the current print number counting counter 34 in step P44 and stored in the main printing stop position storage memory M4. On the other hand, if not, the process proceeds to Step P54 described later.

  Next, after sending the final printing stop position (current count value of the counter 34 for counting the number of printed sheets) to the A side and B side stacker and bundler control devices 50A and 50B in step P45, the A side and B side in step P46. When the reception confirmation signal of the final printing stop position is transmitted from the side stacker / bundler control device 50A, 50B, it is determined in step P47 whether or not the output of the print sheet count sensor 35 of the web rotary press is ON.

  Next, if yes in step P47, the count value is read from the current print number counting counter 34 and stored in the memory M3 in step P48, and if no, the process proceeds to step P50 described later.

  In step P49, the current count value of the counter 34 for counting the number of printed sheets is transmitted to the A-side and B-side stacker / bundleer control devices 50A and 50B, and then the process proceeds to step P112 described later.

  Next, it is determined whether or not the regular paper switch 29 is turned on in the above-described step P50, and if yes, the count value is read from the current print number counting counter 34 in step P51, and the main printing restart position storage memory M5. If not, the process returns to step P47.

  Next, after the printing restart position (current count value of the counter 34 for counting the number of printed sheets) is transmitted to the A-side and B-side stacker and bundler control devices 50A and 50B in step P52, the A side and B The reception confirmation signal for the final printing resumption position is transmitted from the stacker / bundler control device 50A, 50B on the side, and the process proceeds to step P54 described above.

  Next, in step P54, it is determined whether or not the target print number setting device 33 has been re-input, and if yes, the setting value of the target print number setting device 33 is read in step P55 and the target print number setting memory is stored. After storing in the memory M2, the process returns to step P14, while if NO, the process immediately returns to step P14.

  In the present embodiment, the routine of Step P32 to Step P42, the routine of Step P43 to Step P53, and the routine of Step P54 to Step P55 described above are explained in time series. At least one is performed out of order.

  With the above operation flow, the data on the same pattern and the target print number → printing start signal → the count value of the current print number counting counter 34 for the A side and B side stacker / bundler control devices 50A, 50B. When each information is transmitted in turn, when the waste paper signal is turned ON and the normal paper switch 29 is turned OFF, the final printing stop position for the A-side and B-side stacker / bundler control devices 50A and 50B → current Each piece of information is transmitted in the order of the count value of the printing sheet count counter 34 and the final printing restart position. Further, when a target print number is input to the target print number setting unit 33, it is stored in the target print number storage memory M2.

  Next, after 0 is overwritten in the count value C storage memory M6 in step P56 described above, it is determined in step P57 whether or not the current number of normal sheets has been transmitted from the A-side stacker / bundler control device 50A. If so, in step P58, the current sheet number is received from the A-side stacker / bundler control device 50A and stored in the current sheet number storage memory M7 on the A side. Transition.

  Next, after reading the count value C from the memory M6 in step P59, 1 is added to the count value C in step P60, and the count value C storage memory M6 is overwritten.

  Next, after a reception confirmation signal for the number of sheets is sent to the A-side stacker / bundler controller 50A in step P61, is the current sheet number sent from the B-side stacker / bundleer controller 50B in step P62 described above? Judge whether or not.

  Next, if yes in step P62, in step P63, the current sheet number is received from the B-side stacker / bundler control device 50B and stored in the B-side current sheet number storage memory M8. If so, the process proceeds to Step P67 described later.

  Next, after the count value C is read from the memory M6 in step P64, 1 is added to the count value C in step P65 to overwrite the count value C storage memory M6. In step P66, a reception confirmation signal for the number of sheets is sent to the B-side stacker / bundler control device 50B, and then the count value C is read from the memory M6 in step P67 described above.

  Next, in step P68, it is determined whether or not the count value C = 2. If yes, data indicating whether the picture is the same is read from the memory M1 in step P69. If no, the process returns to step P57.

  Next, in step P70, it is determined whether or not the data for the same picture = 1. If yes, the current number of sheets on the A side is read from the memory M7 in step P71. Control goes to step P77.

  Next, in step P72, the current number of normal sheets on the B side is read from the memory M8, and in step P73, the current number of normal sheets on the B side is added to the current number of normal sheets on the A side. The number of sheets is calculated and stored in the memory M9. Next, after reading the target print number from the memory M2 in step P74, the target total print number is calculated by multiplying the target print number by 2 in step P75 and stored in the memory M10.

  Next, in step P76, it is determined whether or not the current total number of regular sheets is equal to or greater than the target total number of printed sheets. If yes, a print completion signal is transmitted to the A side and B side stackers and bundlers in step P76-a. On the other hand, the process proceeds to Step P140 described later.

  Next, after reading the current number of normal sheets on the A side from the memory M7 in step P77, the current number of normal sheets on the B side is read from the memory M8 in step P78. Next, in step P79, it is determined whether or not the current number of normal sheets on the A side ≦ the current number of normal sheets on the B side.

  Next, if yes in step P79, after reading the target print number from the memory M2 in step P80, it is determined in step P81 whether or not the current normal paper number on the A side = target print number. If there is, the process proceeds to the above-described Step P76-a, and if not, the process returns to Step P14.

  On the other hand, if NO in step P79, after reading the target number of prints from the memory M2 in step P82, it is determined in step P83 whether the current number of normal sheets on the B side is equal to the target number of prints. For example, the process proceeds to the above-described step P76-a, and if not, the process returns to step P14.

  Next, after the count value C storage memory M6 is overwritten with 0 in step P84 described above, it is determined in step P85 whether or not the current normal sheet count has been transmitted from the A-side stacker / bundler control device 50A. If so, in step P86, the current sheet number is received from the A-side stacker / bundler control device 50A and stored in the A-side current sheet number storage memory M7. If not, the process proceeds to step P90 described later. Transition.

  Next, after reading the count value C from the memory M6 in step P87, 1 is added to the count value C in step P88 to overwrite the count value C storage memory M6.

  Next, after a reception confirmation signal for the number of sheets is sent to the A-side stacker / bundler control device 50A in step P89, is the current sheet number of sheets sent from the B-side stacker / bundler control device 50B in step P90 described above? Judge whether or not.

  Next, if yes in step P90, in step P91, the current normal sheet number is received from the B-side stacker / bundler control device 50B and stored in the B-side current normal sheet number storage memory M8. If so, the process proceeds to Step P95 described later.

  Next, after the count value C is read from the memory M6 in step P92, 1 is added to the count value C in step P93 to overwrite the count value C storage memory M6. In step P94, a reception confirmation signal for the number of sheets is sent to the B-side stacker / bundler controller 50B, and the count value C is read from the memory M6 in step P95 described above.

  Next, in step P96, it is determined whether or not the count value C = 2. If yes, data indicating whether or not the same picture is read from the memory M1 is read in step P97. If not, the process returns to step P85.

  Next, in step P98, it is determined whether or not the data indicating whether or not the same picture is equal to 1. If yes, the current number of sheets on the A side is read from the memory M7 in step P99. The process proceeds to step P105.

  Next, in step P100, the current number of normal sheets on the B side is read from the memory M8, and in step P101, the current number of normal sheets on the B side is added to the current number of normal sheets on the A side. The number of sheets is calculated and stored in the memory M9. Next, after reading the target print number from the memory M2 in step P102, the target total print number is calculated by multiplying the target print number by 2 in step P103 and stored in the memory M10.

  Next, in step P104, it is determined whether or not the current total number of regular sheets is equal to or greater than the target total number of printed sheets. If yes, a print completion signal is transmitted to the A side and B side stackers and bundlers in step P104-a. On the other hand, the process proceeds to Step P140, which will be described later.

  Next, after reading the current number of normal sheets on the A side from the memory M7 in step P105, the current number of normal sheets on the B side is read from the memory M8 in step P106. Next, in step P107, it is determined whether or not the current number of normal sheets on the A side ≦ the current number of normal sheets on the B side.

  Next, if yes in step P107, after reading the target number of prints from the memory M2 in step P108, it is determined in step P109 whether or not the current normal sheet number on the A side = the target print number. If there is, the process proceeds to the above-described Step P104-a, and if not, the process returns to Step P39.

  On the other hand, if NO in step P107, after reading the target print number from the memory M2 in step P110, it is determined in step P111 whether the current normal sheet number on the B side = the target print number. For example, the process proceeds to the above-described step P104-a, but if not, the process returns to step P39.

  Next, after the count value C storage memory M6 is overwritten with 0 in step P112 described above, it is determined in step P113 whether or not the current normal sheet count has been transmitted from the A-side stacker / bundler control device 50A. If so, in step P114, the current sheet number is received from the A-side stacker / bundler controller 50A and stored in the current sheet number storage memory M7 on the A side. If not, the process proceeds to step P118 described later. Transition.

  Next, after the count value C is read from the memory M6 in step P115, 1 is added to the count value C in step P116 to overwrite the count value C storage memory M6.

  Next, in step P117, a reception confirmation signal for the number of sheets is sent to the A-side stacker / bundler controller 50A, and then the current sheet number is sent from the B-side stacker / bundler controller 50B in step P118. Determine whether.

  If yes in step P118, in step P119, the current sheet number is received from the B-side stacker / bundleer control device 50B and stored in the B-side current sheet number storage memory M8. If so, the process proceeds to Step P123 described later.

  Next, after reading the count value C from the memory M6 in step P120, 1 is added to the count value C in step P121 to overwrite the count value C storage memory M6. In step P122, a reception confirmation signal for the number of sheets is sent to the B-side stacker / bundler controller 50B, and the count value C is read from the memory M6 in step P123 described above.

  Next, in step P124, it is determined whether or not the count value C = 2. If yes, data indicating whether the picture is the same is read from the memory M1 in step P125. If no, the process returns to step P113.

  Next, in step P126, it is determined whether or not the data indicating whether or not the same picture is equal to 1. If yes, the current number of sheets on the A side is read from the memory M7 in step P127. Control goes to step P133.

  Next, in step P128, the current number of normal sheets on the B side is read from the memory M8, and then in step P129, the current number of normal sheets on the B side is added to the current number of normal sheets on the A side. The number of sheets is calculated and stored in the memory M9. Next, after reading the target print number from the memory M2 in step P130, the target total print number is calculated by multiplying the target print number by 2 in step P131 and stored in the memory M10.

  Next, in step P132, it is determined whether or not the current total number of regular sheets is equal to or greater than the target total number of printed sheets. If yes, a print completion signal is transmitted to the A side and B side stackers and bundlers in step P132-a. On the other hand, the process proceeds to Step P140, which will be described later.

  Next, after reading the current sheet number on the A side from the memory M7 in step P133, the current sheet number on the B side is read from the memory M8 in step P134. Next, in step P135, it is determined whether or not the current number of normal sheets on the A side ≦ the current number of normal sheets on the B side.

  Next, if yes in step P135, after reading the target print number from the memory M2 in step P136, it is determined in step P137 whether or not the current normal sheet number on the A side = target print number. If there is, the process proceeds to the above-described Step P132-a. If not, the process returns to Step P50.

  On the other hand, if NO in step P135, after reading the target print number from the memory M2 in step P138, it is determined in step P139 whether the current normal sheet number on the B side = target print number. For example, the process proceeds to the above-described step P132-a, and if not, the process returns to step P50.

  With the above operation flow, the number of sheets fed from the A side and B side stacker and bundler control devices 50A and 50B is received, and in the case of the same pattern, printing is performed when the total value of them exceeds the required number. If the same pattern is not used, printing is terminated when the smaller number of sheets reaches the required number. Note that the determination of the completion of printing in the case of the same pattern is (current total number of printed sheets ≧ target total number of printed sheets). In this case, the total number of printed sheets is always an even number. In some cases, the count value of the current counter for counting the number of normal sheets is an even number and the other is an odd number. In this case, printing is completed when (current total number of printed sheets = target total number of printed sheets + 1). Because it becomes.

  Next, after the start command of ink removing is transmitted to the ink film thickness preparation device 120 in Step P140 described above, the movement of the new web roll 202 to the splicing standby position is sent to the auto paste device 36 in Step P141. A paste preparation start command such as paper edge alignment between the old web roll 201 and the new web roll 202 is transmitted. Next, in step P142, 1 (in operation) is set in the operation status storage memory M36 of the auto paste device. Overwrite.

  Next, after reading the set rotational speed from the rotational speed setter 43 in step P143 and storing it in the previous rotational speed storage memory M37, whether or not a paste preparation completion signal is transmitted from the auto-paste device 36 in step P144. In step P145, 2 (stopped) is overwritten in step P145, and the process proceeds to step P146. If not, the process immediately proceeds to step P146. To do.

  Next, in step P146, the previous rotational speed is read from the memory M37, and in step P147, the rotational speed correction value during deceleration is read from the memory M38. Next, in step P148, the current rotational speed is calculated by subtracting the rotational speed correction value at the time of deceleration from the previous rotational speed, and stored in the memory M39.

  Next, after reading the rotational speed at the time of blanket cleaning from the memory M80 at step P149, it is determined at step P150 whether or not the current rotational speed is smaller than the rotational speed at the time of blanket cleaning. After the rotation speed storage memory M39 is overwritten with the rotation speed at the time of blanket cleaning, the current rotation speed is read from the memory M39 in step P151. If the answer is no, the process proceeds to step P151.

  Next, after overwriting the current rotational speed in the command rotational speed storage memory M81 in step P153, the command rotational speed is output to the driving motor driver 44 in step P154. Next, after the current rotational speed is overwritten in the previous rotational speed storage memory M37 in step P155, it is determined in step P156 whether an ink removal completion signal has been transmitted from the ink film thickness creating device 120.

  If yes in step P156, a print stop command is output to each of the printing units 102a to 102d in step P157, while if no, the process returns to step P144.

  Next, after reading the previous rotational speed from the memory M37 in step P158, the rotational speed correction value at the time of deceleration is read from the memory M38 in step P159. Next, at step P160, the current rotational speed is calculated by subtracting the rotational speed correction value at the time of deceleration from the previous rotational speed, and stored in the memory M39.

  Next, after reading the rotational speed at the time of blanket cleaning from the memory M80 at step P161, it is determined at step P162 whether the current rotational speed is smaller than the rotational speed at the time of blanket cleaning. Are read from the memory M39, and the current rotational speed is overwritten in the command rotational speed storage memory M81 in step P164.

  Next, after the command rotational speed is output to the driving motor driver 44 in step P165, the current rotational speed is overwritten in the previous rotational speed storage memory M37 in step P166, and the process returns to step P158.

  On the other hand, if yes in Step P162, the rotational speed at blanket cleaning is read from the memory M80 at Step P167, and then the current rotational speed storage memory M39 is overwritten with the rotational speed at blanket cleaning at Step P168.

  Next, after reading the current rotational speed from the memory M39 in step P169, the current rotational speed is overwritten in the command rotational speed storage memory M81 in step P170. Next, in step P171, the command rotational speed is output to the driving motor driver 44.

  Next, after transmitting a cleaning start command to the blanket cleaning apparatuses 121a and 121b in step P172, it is determined whether or not a paste preparation completion signal is transmitted from the auto paste apparatus 36 in step P173. In P174, 2 (stopped) is overwritten in the operation status storage memory M36 of the auto-paste apparatus, and the process proceeds to Step P175. On the other hand, if not, the process proceeds to Step P175.

  Next, in step P175, it is determined whether or not a cleaning completion signal is transmitted from the blanket cleaning devices 121a and 121b. If yes, whether or not a paste preparation completion signal is transmitted from the auto paste device 36 in step P176. If NO, the process returns to Step P173.

  Next, if yes in step P176, after overwriting 2 (stopped) in the operation status storage memory M36 of the auto paste device in step P177, the previous rotational speed is read from the memory M37 in step P178, If not, the process proceeds to step P178.

  Next, after reading the rotational speed correction value at the time of deceleration from the memory M38 at step P179, the current rotational speed is calculated by subtracting the rotational speed correction value at the time of deceleration from the previous rotational speed at step P180, and the memory Store in M39.

  Next, in step P181, it is determined whether or not the current rotational speed <0. If yes, the current rotational speed storage memory M39 is overwritten with 0 in step P183, and then the current rotational speed is stored in the memory M39 in step P182. If the answer is no, the program immediately goes to Step P182.

  Next, after overwriting the current rotational speed in the command rotational speed storage memory M81 in step P184, the command rotational speed is output to the driving motor driver 44 in step P185. Next, in step P186, the current rotational speed is overwritten in the previous rotational speed storage memory M37.

  Next, after reading the contents of the operation status storage memory M36 of the auto paste device in step P187, it is determined in step P188 whether the contents of the operation status storage memory M36 of the auto paste device = 2. If yes, the process proceeds to step P189, which will be described later. If no, the process returns to step P176.

  When printing is completed by the above operation flow, an ink removal start command is transmitted to the ink film thickness creating device 120, which is an automatic switching device for job switching, and paste preparation is started to the auto paste device 36. A command is transmitted, and then a cleaning start command is transmitted to the blanket cleaning devices 121a and 121b.

  Next, after the slow rotational speed is read from the memory M82 in Step P189 described above, the current rotational speed storage memory M39 is overwritten with the slow rotational speed in Step P190. Next, after reading the current rotational speed from the memory M39 in Step P191, the current rotational speed is overwritten in the command rotational speed storage memory M81 in Step P192.

  Next, after the command rotational speed is output to the driving motor driver 44 in step P193, a paste start command is transmitted to the auto-paste device 36 in step P194. In step P195, 1 (in operation) is overwritten in the operation state storage memory M36 of the auto-paste apparatus.

  Next, after the current paper width is read from the memory M32 in step P197, a preset start command and the current paper width are transmitted to the web preset device 122 in step P198.

  Next, after 1 (in operation) is overwritten in the memory M83 for storing the operation status of the web preset device in step P199, a pre-inking preparation start command (point key control device (PQC) is sent to the ink film thickness creating device 120 in step P200. ) Send a preset). Next, in step P201, 1 (in operation) is overwritten in the operation state storage memory M84 of the ink film thickness producing device.

  Next, in step P202, it is determined whether or not a paste completion command has been transmitted from the auto paste device 36. If yes, 2 (stopped) is set in the operation status storage memory M36 of the auto paste device in step P203. On the other hand, if not, the process proceeds to Step P206 described later.

  Next, in step P206, it is determined whether or not a preset completion signal is transmitted from the web preset device 122. If yes, 2 is stored in the operation status storage memory M83 of the web preset device in step P207 (stopped). ) Is overwritten and the process proceeds to step P208, and if not, the process immediately proceeds to step P208.

  Next, in step P208, it is determined whether or not a pre-inking preparation completion signal is transmitted from the ink film thickness creating device 120. If yes, in step P209, the ink film thickness creating device stores an operation status storage memory M84. 2 (stopped) is overwritten and the process proceeds to step P210. If not, the process immediately proceeds to step P210.

  Next, after reading the contents of the operation status storage memory M36 of the auto-paste device in step P210, it is determined in step P211 whether the contents of the operation status storage memory M36 of the auto-paste device = 2. If yes, read the contents of the operation status storage memory M83 of the web preset device in Step P212, and then go to Step P213. If not, return to Step P202.

  Next, in step P213, it is determined whether or not the content of the operation status storage memory of the web preset device = 2. If yes, the process proceeds to step P214. If not, the process returns to step P202.

  Next, in step P214, it is determined whether or not a pre-inking preparation completion signal has been transmitted from the ink film thickness creating device 120. If yes, 2 is stored in the operation state storage memory M84 of the ink film thickness creating device in step P215. After overwriting (stopped), the process proceeds to step P218. If not, the process immediately proceeds to step P218.

  Next, after an operation start command is transmitted to the dancer devices 123a and 123b in step P218, a plate change start command is transmitted to the automatic plate changers 124a and 124b in step P219.

  Next, in step P220, it is determined whether or not a pre-inking preparation completion signal is transmitted from the ink film thickness creating device 120. If yes, 2 is stored in the memory M84 for storing the operation status of the ink film thickness creating device in step P221. After overwriting (stopped), the process proceeds to step P222. If not, the process immediately proceeds to step P222.

  Next, in step P237, it is determined whether or not a plate change completion signal is transmitted from the automatic plate changers 124a and 124b. If yes, the slow rotational speed is read from the memory M82 in step P238. If not, the process returns to Step P235.

  Next, after overwriting the slow rotational speed in the current rotational speed storage memory M39 in step P224, the current rotational speed is read from the memory M39 in step P225. Next, after overwriting the current rotational speed in the command rotational speed storage memory M81 in step P226, the command rotational speed is output to the driving motor driver 44 in step P227.

  Next, in step P228, a paper feed stop command is transmitted to the auto-paste device 36 and the infeed device 125, and in step P229, whether or not a pre-inking preparation completion signal is transmitted from the ink film thickness creating device 120 is determined. to decide.

  Next, if yes in Step P229, the operation state storage memory M84 of the ink film thickness forming apparatus is overwritten with 2 (stopped) in Step P230, and then the process proceeds to Step P231. The process proceeds to step P231.

  Next, in step P231, it is determined whether or not a paper slack removal completion signal is transmitted from the dancer devices 123a and 123b. If yes, an operation end command is transmitted to the dancer devices 123a and 123b in step P232. If not, the process returns to Step P229.

  Next, in step P233, it is determined whether or not a pre-inking preparation completion signal has been transmitted from the ink film thickness creating device 120. If yes, 2 is stored in the operation state storage memory M84 of the ink film thickness creating device in step P234. After overwriting (stopped), the process proceeds to step P235. If not, the process proceeds to step P235 immediately.

  Next, after the folding specification is read from the memory M34 in step P235, the folding specification switching start command and folding specification are transmitted to the folding specification switching device 126 in step P236.

  Next, in step P237, it is determined whether or not a pre-inking preparation completion signal has been transmitted from the ink film thickness creating device 120. If yes, 2 is stored in the operation status storage memory M84 of the ink film thickness creating device in step P238. After overwriting (stopped), the process proceeds to step P239. On the other hand, if no, the process proceeds to step P239.

  Next, in step P239, it is determined whether or not a folding specification switching completion signal is transmitted from the folding specification switching device 126. If yes, the process proceeds to step P240 to be described later. If not, the process returns to step P237. .

  Next, in step P240, it is determined whether or not a pre-inking preparation completion signal is transmitted from the ink film thickness creating device 120. If yes, in step P241, the ink film thickness creating device stores the operation status storage memory M84. After overwriting 2 (stopped), the process proceeds to step P242. On the other hand, if no, the process proceeds to step P242.

  When printing is completed by the above operation flow, following the job switching start command described above, a paste start command to the auto paste device 36 → a preset start command to the web preset device 122 → dancer devices 123a and 123b. Are transmitted in the order of the operation start command to the automatic plate changer 124a and 124b and the folding specification switching start command to the folding specification switching unit 126.

  Next, after the temperature rising start command is transmitted to the drying device 103 in Step P242, it is determined whether or not a pre-inking preparation completion signal is transmitted from the ink film thickness creating device 120 in Step P243. In step P244, 2 (stopped) is overwritten in the operation state storage memory M84 of the ink film thickness creating apparatus, and then the process proceeds to step P245. On the other hand, if not, the process directly proceeds to step P245.

  Next, it is determined whether or not a temperature raising completion signal is transmitted from the drying apparatus 103 in step P245. If yes, whether or not a pre-inking preparation completion signal is transmitted from the ink film thickness creating apparatus 120 in step P246. If NO, the process returns to Step P243.

  Next, if yes in Step P246, the operation state storage memory M84 of the ink film thickness creating apparatus is overwritten with 2 (stopped) in Step P247 and then the process proceeds to Step P248. Control goes to step P248.

  Next, after reading the contents of the operation status storage memory M84 of the ink film thickness creation device in step P248, it is determined in step P249 whether the contents of the operation status storage memory M84 of the ink thickness creation device = 2. If YES in step P250, the slow rotation speed is read from the memory M82. If NO, the process returns to step P246.

  Next, after overwriting the slow rotational speed in the previous rotational speed storage memory M37 in step P251, the previous rotational speed is read from the memory M37 in step P252. Next, in step P253, the rotational speed correction value at the time of acceleration is read from the memory M89.

  Next, in Step P254, the current rotational speed is calculated by adding the rotational speed correction value at the time of acceleration to the previous rotational speed and stored in the memory M39. Then, in Step P255, the current rotational speed is stored in the command rotational speed storage memory M81. Override the rotation speed of. Next, in step P256, the command rotational speed is output to the driving motor driver 44.

  Next, after reading the current rotational speed from the memory M39 in step P257, the rotational speed at the start of pre-inking is read from the memory M90 in step P258. Next, in step P259, it is determined whether or not the current rotational speed is higher than the rotational speed at the start of pre-inking. If yes, the process proceeds to step P261 described later. If not, the previous rotational speed is stored in step P260. The memory M37 is overwritten with the current rotation speed, and the process returns to Step P252.

  Next, after a pre-inking start command is transmitted to the ink film thickness creating device 120 in step P261 described above, the previous rotational speed is read from the memory M37 in step P262. Next, after the rotational speed correction value at the time of acceleration is read from the memory M89 in step P263, the current rotational speed is calculated by adding the rotational speed correction value at the time of acceleration to the previous rotational speed in step P264, Store in the memory M39.

  Next, after overwriting the current rotational speed in the command rotational speed storage memory M81 in step P265, the command rotational speed is output to the driving motor driver 44 in step P266. Next, in step P267, the current rotational speed is overwritten in the previous rotational speed storage memory M37.

  Next, in step P268, it is determined whether or not a pre-inking completion signal is transmitted from the ink film thickness creating device 120. If yes, a print start command is output to each of the printing units 102a to 102d in step P269. If not, the process returns to Step P262.

  Next, in step P270, the previous rotation speed is read from the memory M37, and in step P271, the rotation speed correction value at the time of acceleration is read from the memory M89. Next, at step P272, the current rotational speed is calculated by adding the rotational speed correction value at the time of acceleration to the previous rotational speed, and stored in the memory M39.

  Next, in step P273, the set rotational speed is read from the rotational speed setter 43 and stored in the memory M35. Then, in step P274, it is determined whether or not the current rotational speed is smaller than the set rotational speed. While overwriting the current rotational speed in the command rotational speed storage memory M81, if not, the process proceeds to Step P278 described later.

  Next, in step P276, the command rotational speed is output to the driving motor driver 44, and in step P277, the previous rotational speed storage memory M37 is overwritten with the current rotational speed, and the process returns to step P270.

  Next, after the set rotational speed is read from the rotational speed setter 43 in step P278 and stored in the memory M35, the set rotational speed is overwritten in the current rotational speed storage memory M39 in step P279.

  Next, after reading the current rotational speed from the memory M39 in step P280, the current rotational speed is overwritten in the command rotational speed storage memory M81 in step P281. Next, in step P282, the command rotational speed is output to the driving motor driver 44, and the process returns to step P5.

  When printing is completed according to the above operation flow, following the job switching start command described above, a temperature increase start command to the drying device 103 → a preinking start command to the ink film thickness creating device 120 are transmitted in this order. Thereafter, a print start command is output to each of the printing units 102a to 102d.

  On the other hand, the control operation of the A-side and B-side stacker / bundler control devices 50A, 50B will be described in detail with reference to the operation flowcharts of FIGS. 19A, 19B, and 20A to 20D.

  First, after initialization processing in step P1, data on whether or not the same pattern and the target number of prints are transmitted from the control device 10 of the web rotary press in step P2, and then the control device of the web rotary press in step P3. The data indicating whether or not the image is the same and the target print number are received from 10 and stored in the memory M40 and the memory M41.

  Next, in step P4, data indicating whether or not the images are the same and a reception confirmation signal for the target number of prints are transmitted to the control device 10 of the web rotary press. Then, in step P5, the main printing start signal is transmitted from the control device 10 of the web rotary press. Is transmitted, in step P6, a reception confirmation signal for the final printing start signal is transmitted to the control device 10 of the web rotary press.

  Next, in step P7, a reset signal and an enable signal are output to the current sheet count counter 62, and in step P8, the output of the reset signal to the current sheet count counter 62 is stopped.

  Next, after overwriting the count value M of the memory M42 with 0 in step P9, the count value N of the memory M43 is overwritten with 0 in step P10.

  Next, in step P11, it is determined whether or not the final printing stop position has been transmitted from the control device 10 of the web rotary press. If yes, the count value M is read from the memory M42 in step P12. For example, the process proceeds to Step P16 described later.

Next, in step P13, 1 is added to the count value M of the memory M42 and overwriting is performed. Then, in step P14, the main printing stop position is received from the control device 10 of the web rotary press, and the main printing stop position storage memory M44. At the Mth address position.
Next, after the reception confirmation signal of the final printing stop position is transmitted to the control device 10 of the web rotary press in step P15, is the final printing restart position transmitted from the control device 10 of the web rotary printing press in step P16 described above? Judge whether or not.

  Next, if yes in step P16, the count value N is read from the memory M43 in step P17. If no, the process proceeds to step P21 described later. Next, in step P18, 1 is added to the count value N of the memory M43 and overwritten.

  Next, in step P19, the final printing restart position is received from the control device 10 of the web rotary press and stored in the Nth address position of the main printing restart position storage memory M45. A reception confirmation signal at the final printing restart position is transmitted to the control device 10.

  According to the above operation flow, after receiving the data indicating whether or not the same image and the target number of prints are received from the control device 10 of the web rotary press, the main printing start signal is received, and the main printing is performed from the control device 10 of the web rotary press. When the stop position and the final printing restart position are received, the positions are stored in the address positions corresponding to the received order (M or N).

  Next, in step 21 described above, it is determined whether or not the current count value of the counter 34 for counting the number of printed sheets has been transmitted from the control device 10 of the web rotary press, and if yes, in step P22, the web rotary press. The count value of the current print sheet count counter 34 is received from the control device 10 and stored in the print sheet storage memory M46 of the current web rotary press. It is determined whether a print completion signal has been transmitted from the control device.

  Next, if yes in step P21-a, the process returns to step P2, while if no, the process returns to step P11. Next, after overwriting 1 in the count value MM of the memory M47 in step P23, the count value MM is read from the memory M47 in step P24. Next, in step P25, the count value M is read from the memory M42.

  Next, in step P26, it is determined whether or not the count value MM> the count value M. If yes, the process proceeds to step P36 described later. If no, the count value MM is read from the memory M47 in step P27.

  Next, in step P28, the MMth final printing stop position is read from the MMth address position in the main printing stop position storage memory M44 and stored in the memory M48. Then, in step P29, the number of sheets from the memory M67 to the reject device 64 is read. (The number of sheets from the web rotary press to the reject device 64) is read.

  Next, at step P30, the number of sheets up to the reject device 64 is added to the MMth final printing stop position to calculate the MMth rejection start position, and the result is stored in the memory M68. Read the number of pages printed on a rotary printing press.

  Next, in step P32, it is determined whether or not the MM-th rejection start position = current number of prints of the web rotary press. If yes, a rejection signal is output to the rejection device 64 in step P33, and step P34 described later is performed. On the other hand, if NO, the process directly goes to Step P34.

  Next, after reading the count value MM from the memory M47 in step P34 described above, 1 is added to the count value MM in the memory M47 and overwritten in step P35, and the process returns to step P24.

  Next, after the count value NN of the memory M53 is overwritten with 1 in step P36 described above, the count value NN is read from the memory M53 in step P37. Next, in step P38, the count value N is read from the memory M43.

  Next, in step P39, it is determined whether or not the count value NN> the count value N. If yes, the process proceeds to step P49 described later. If no, the count value NN is read from the memory M53 in step P40.

  Next, in step P41, the NNth final printing restart position is read from the NNth address position of the final printing restart position storage memory M45 and stored in the memory M54. Then, in step P42, the number of sheets from the memory M67 to the reject device 64 is read. Is read.

  Next, in step P43, the NNth rejection completion position is calculated by adding the number of sheets up to the rejection device 64 to the NNth final printing restart position, and stored in the memory M69. Then, in step P44, the current winding paper is read from the memory M46. Read the number of pages printed on a rotary printing press.

  Next, in step P45, it is determined whether or not the NNth rejection completion position = the current number of printed pages of the web rotary press. If yes, output of the rejection signal to the rejection device 64 is stopped in step P46 and described later. On the other hand, the process proceeds to step P47.

  Next, after reading the count value NN from the memory M53 at the above-described Step P47, 1 is added to the count value NN of the memory M53 and overwritten at Step P48, and the process returns to Step P37.

  With the above operation flow, the reject device 64 is operated corresponding to the main printing stop position and the main printing resuming position, and the waste paper (scrap paper) can be reliably removed.

  Next, after overwriting 1 in the count value MM of the memory M47 in Step P49 described above, the count value MM is read from the memory M47 in Step P50. In step P51, the count value M is read from the memory M42.

  Next, in step P52, it is determined whether or not the count value MM> the count value M. If yes, the process proceeds to step P62 described later. If no, the count value MM is read from the memory M47 in step P53.

  Next, in step P54, the MMth final printing stop position is read from the MMth address position in the main printing stop position storage memory M44 and stored in the memory M48. Then, in step P55, a small bundle paper supply check is performed from the memory M70. The number of sheets up to the sensor 63 (the number of sheets from the web rotary press to the small bundle paper supply confirmation sensor 63) is read.

  Next, in step P56, the number of sheets up to the small bundle paper supply confirmation sensor 63 is added to the MMth final printing stop position to calculate the MMth count stop position and store it in the memory M71, and then in step P57. The current number of printed sheets of the web rotary press is read from the memory M46.

  Next, in step P58, it is determined whether or not the MMth count stop position = current number of printed sheets of the web rotary press. If yes, an enable signal to the current normal sheet number counting counter 62 is determined in step P59. While the output is stopped and the process proceeds to Step P60 described later, if the result is NO, the process immediately proceeds to Step P60.

  Next, after reading the count value MM from the memory M47 in step P60, the count value MM in the memory M47 is overwritten by adding 1 in step P61, and the process returns to step P50.

  Next, after overwriting 1 in the count value NN of the memory M53 in Step P62 described above, the count value NN is read from the memory M53 in Step P63. Next, in step P64, the count value N is read from the memory M43.

  Next, in step P65, it is determined whether or not the count value NN> the count value N. If yes, the process proceeds to step P75 described later. If no, the count value NN is read from the memory M53 in step P66.

  Next, in step P67, the NNth final printing restart position is read from the NNth address position of the main printing restart position storage memory M45 and stored in the memory M54. Then, in step P68, a small bundle paper supply check is performed from the memory M70. The number of sheets up to the sensor 63 is read.

  Next, in step P69, the number of sheets up to the small bundle paper supply confirmation sensor 63 is added to the NNth final printing restart position to calculate the NNth count restart position, and the result is stored in the memory M72, and then in step P70. The current number of printed sheets of the web rotary press is read from the memory M46.

  Next, in step P71, it is determined whether or not the NNth count restart position is the current number of pages printed by the web rotary press. If yes, an enable signal is output to the current normal sheet number counting counter 62 in step P72. Then, the process proceeds to step P73, which will be described later.

  Next, after reading the count value NN from the memory M53 in the above-described step P73, 1 is added to the count value NN in the memory M53 and overwritten in step P74, and the process returns to step P63.

  Next, the count value is read from the current sheet count counter 62 in step P75 and stored in the current sheet count storage memory M73. Then, in step P76, the current value is sent to the controller 10 of the web rotary press. Send the number of sheets. Next, when a normal sheet number reception confirmation signal is transmitted from the control device 10 of the web rotary press in step P77, the process returns to step P11.

  According to the above operation flow, the current normal sheet count counter 62 is operated in correspondence with the main printing stop position and the main printing restart position.

  In this way, in this embodiment, the web-fed rotary printing machine cuts the web with the slitter 109 in the left-right direction, and then discharges the signatures cut in the front-rear direction to the A-side and B-side stacker and bundlers 115A and 115B. In 100, the number of sheets fed from the A side and B side stacker / bundler control devices 50A and 50B is counted, and if the same pattern is used, printing is terminated when the total value of these sheets exceeds the required number. If the same pattern is not used, printing is terminated when the smaller number of sheets reaches the required number.

  Further, each automatic switching device for setting the setting of the web rotary press in accordance with the next printed matter is automatically operated in response to the print completion signal.

  As a result, the burden on the operator can be reduced by automation, the web rotary press can be stopped as quickly as possible, and the operating rate can be improved by eliminating waste of printing materials as much as possible.

  FIGS. 21A to 21C are block diagrams of a control device for a web rotary printing press showing Embodiment 3 of the present invention, FIGS. 22A to 22D are operation flow diagrams of the control device for the web rotary press, and FIGS. 23A to 23D are web winding papers. FIG. 24A and FIG. 24B are operation flow diagrams of the control device of the web rotary press, and FIGS. 25A to 25D are operation flow diagrams of the control device of the web rotary press, FIG. 26A and FIG. 26B is an operation flow diagram of the control device of the web rotary press, FIGS. 27A to 27D are operation flow diagrams of the control device of the web rotary press, and FIGS. 28A and 28B are operation flow diagrams of the control device of the web rotary press. 29A to 29D are operation flowcharts of the control device of the web rotary press, and FIGS. 30A to 30D are operation flow diagrams of the control device of the web rotary printing press, FIG. And FIG 31C shows an operational flowchart of the control device of the web rotary printing press.

  This is because the present invention is applied to a web-fed rotary printing press 100 that discharges printed matter on the A-side and B-side discharge conveyors in place of the A-side and B-side stacker and bundler devices 115A and 115B in the first and second embodiments. This is an applied example. That is, an example in which the control device 10 of the web-fed rotary printing press counts the number of regular sheets based on the information on the number of regular sheets on the A-side and B-side delivery conveyors, and the printing is terminated when the number of regular sheets reaches the required number. It is. Since other configurations are the same as those of the first and second embodiments, the redundant description will be omitted with reference to FIGS. 32 to 38 and FIG.

  That is, as shown in FIGS. 21A to 21C, the control device 10 of the web rotary printing press includes the CPU 11, the ROM 12, the RAM 13, the input / output devices 15m to 15r, and the interface 16 all connected by a BUS (bus line). .

  In addition, the BUS (bus line) includes a data storage memory M1, a target print number storage memory M2, a main printing stop position storage memory M4, a main printing restart position storage memory M5, and a current total correctness. A paper number storage memory M9 and a target total print number storage memory M10 are connected.

  Further, the BUS (bus line) includes a memory M11 for storing a count value M, a memory M12 for storing a count value N, a memory M13 for storing the number of prints of the current web rotary press, a memory M14 for storing a count value MM, and an MMth memory. The final printing stop position storage memory M15, the number-of-sheets storage memory M16 up to the A-side rejection device, the A-side MM-th rejection start position storage memory M17, and the number-of-sheets storage memory M18 and B up to the B-side rejection device The MMth rejection start position storage memory M19, the count value NN storage memory M20, and the NNth final printing restart position storage memory M21 are connected.

  Further, the A side NNth rejection completion position storage memory M22, the B side NNth rejection completion position storage memory M23, and the paper supply confirmation sensor of the A side discharge conveyor section are also connected to the BUS (bus). Sheet memory M24, A-side MMth count stop position storage memory M25, B-side sheet discharge conveyor section paper supply confirmation sensor M26 and B-side MMth count stop position The memory M27, the NNth count restart position storage memory M28 on the A side, the NNth count restart position storage memory M29 on the B side, and the count value storage memory of the current sheet count counter on the A side M30 is connected to the count value storage memory M31 of the current sheet count counter on the B side.

  Further, the current paper width storage memory M32, the previous paper width storage memory M33, the folding specification storage memory M34, the set rotational speed storage memory M35, and the operation status storage memory of the auto-paste device are included in the BUS (bus). M36, the previous rotational speed storage memory M37, the rotational speed correction value storage memory M38 during deceleration, and the current rotational speed storage memory M39 are connected.

  Further, the BUS (bus bar) includes a rotational speed storage memory M80, a command rotational speed storage memory M81, a slow rotational speed storage memory M82, an operation status storage memory M83 of the web preset device, and an ink for blanket cleaning. An operation state storage memory M84 of the film thickness creation device, a rotational speed correction value storage memory M89 at the time of acceleration, and a rotational speed storage memory M90 at the start of pre-inking are connected.

  The input / output device 15a includes an identical picture setting switch 26, a setting completion switch 27, a print start switch 28, a regular paper switch (self-holding switch) 29, an input device 30 such as a keyboard, and a display 31 such as a CRT or display. An output device 32 such as a printer or a floppy disk (registered trademark) drive is connected.

  A target print number setting device 33 is connected to the input / output device 15b. A paper width setting device 41 is connected to the input / output device 15c. A folding specification setting device 42 is connected to the input / output device 15d. A rotation speed setting unit 43 is connected to the input / output device 15e.

  The input / output device 15f is connected with a sensor 35 for counting the number of printed sheets of a web rotary press. The input / output device 15g is connected with a counter 34 for counting the current number of printed sheets, and the counter 34 for counting the number of currently printed sheets is connected with a sensor 35 for counting the number of printed sheets of a web rotary press. The input / output device 15h is connected to a counter 34 for counting the current number of printed sheets, to which a reset signal and an enable signal are output.

  The input / output device 15n is connected to a current sheet count counter 38A on the A side. The current sheet count counter 38A on the A side is connected to the current sheet count counter 38A on the A side via an AND circuit. The counting sensor 35 and the A-side discharge conveyor section paper supply confirmation sensor 39A are connected. The input / output device 15o is connected to the current A-side counter for counting the number of normal sheets 38A, to which a reset signal and an enable signal are transmitted.

  The input / output device 15p is connected to a B-side current sheet count counter 38B. The B-side sheet count counter 38B is connected to the B-side current sheet count counter 38B via an AND circuit. The counting sensor 35 and the B-side paper discharge conveyor section paper supply confirmation sensor 39B are connected. The input / output device 15q is connected to a current regular sheet count counter 38B on the B side, to which a reset signal and an enable signal are transmitted.

  An A-side reject device 40A and a B-side reject device 40B are connected to the input / output device 15r, and a reject signal is transmitted to them.

  The auto paste device 36 and the print quality inspection device 37 described above are connected to the input / output device 15i, from which a waste paper signal is input.

  A driving motor 45 is connected to the input / output device 15j via a D / A converter 17 and a driving motor driver 44. A driving motor rotary encoder 46 connected to the driving motor 45 is connected to the driving motor driver 44.

  The input / output device 15m includes a first color printing unit (operation panel) 102a, a second color printing unit (operation panel) 102b, a third color printing unit (operation panel) 102c, and a fourth color printing unit (operation panel) 102d. Is connected.

  The interface 16 includes an ink film thickness preparation device 120, an auto paste device 36, a blanket cleaning device 121a, 121b, a web preset device 122, dancer devices 123a, 123b, automatic plate change devices 124a, 124b, and an infeed device 125. The folding specification switching device 126 and the drying device 103 are connected.

  The control operation of the control apparatus 10 of the web rotary press having the above-described configuration is shown in FIGS. 22A to 22D, 23A to 23D, 24A and 24B, 25A to 25D, 26A and 26B, and 27A to 27A. 27A, 28A and 28B, FIGS. 29A to 29D, FIGS. 30A to 30D, and FIGS. 31A to 31C.

  First, after initialization processing in step P1, it is determined in step P2 whether or not the setting completion switch 27 is ON. If yes, if the print start switch 28 is turned ON in step P3, printing starts in step P4. Is done.

  Next, in step P5, a reset signal and an enable signal are output to the current print number counting counter 34. Then, in step P6, the output of the reset signal to the current print number counting counter 34 is stopped.

  Next, when the regular paper switch (self-holding type switch) 29 is turned on in step P7, a reset signal and an enable signal are output to the current regular paper sheet count counters 38A and 38B on the A side and B side in step P8. To do. Next, in step P9, the output of the reset signal to the current normal sheet count counters 38A and 38B on the A side and B side is stopped.

  Next, after overwriting the count value M of the memory M11 with 0 in step P10, the count value N of the memory M12 is overwritten with 0 in step P11. Next, in step P12, it is determined whether or not the output of the printing sheet count sensor 35 of the web rotary press is ON. If yes, the process proceeds to step P44 described later, and if not, the process proceeds to step P28 described later. To do.

  If NO in step P2, it is determined in step P13 whether or not the same picture setting switch 26 is ON. If yes, the contents of the data storage memory M1 are read in step P14 to determine whether or not the same picture is set. If not, the process proceeds to Step P18 described later.

  Next, in step P15, it is determined whether or not the content of the data storage memory for the same picture is 0. If yes, 1 (identical) is overwritten in the data storage memory M1 for the same picture in step P16. On the other hand, the process proceeds to step P18. On the other hand, if NO, the data storage memory M1 indicating whether the picture is the same is overwritten with 0 (different) and the process proceeds to step P18.

  Next, in step P18 described above, it is determined whether or not the target print number setting device 33 has been inputted to the target print number setting device 33. If yes, the setting value of the target print number setting device 33 is read in step P19 and stored. After being stored in the memory M2, the process proceeds to step P20. If not, the process immediately proceeds to step P20.

  Next, in step P20, it is determined whether or not a paper width has been input to the paper width setting device 41. If yes, the setting value of the paper width setting device 41 is read in step P23 and overwritten in the current paper width storage memory M32. Thereafter, the process proceeds to step P24. If not, the process immediately proceeds to step P24.

  Next, in step P24, it is determined whether or not a folding specification has been input to the folding specification setting unit 42. If yes, the setting of the folding specification setting unit 42 is read in step P25 and overwritten in the folding specification storage memory M34. Then, the process proceeds to step P26, and if not, the process immediately proceeds to step P26.

  Next, in step P26, it is determined whether or not a rotational speed has been input to the rotational speed setter 43. If yes, the set value of the rotational speed setter 43 is read in step P27, and the set rotational speed storage memory M35. Is overwritten and the process returns to step P2. On the other hand, if no, the process returns to step P2.

  Next, it is determined whether or not the waste paper signal from the auto paste device 36 or the print quality inspection device 37 is turned on in the above-described step P28. If yes, the count value M in the memory M11 is set to 1 in step P29. While adding and overwriting, if not, the process proceeds to Step P35 described later.

  Next, in step P30, the count value is read from the current print number counting counter 34 and stored in the Mth address position of the main printing stop position storage memory M4. Then, in step P31, the print sheet count of the web rotary press is counted. It is determined whether or not the output of the sensor 35 is ON. If yes, the process proceeds to step P140, which will be described later. If not, it is determined in step P32 whether the waste paper signal is OFF.

  Next, if yes in step P32, 1 is added to the count value N of the memory M12 in step P33 and overwriting is performed. Then, in step P34, the count value is read from the counter 34 for counting the current number of printed sheets, and the main printing is resumed. The data is stored in the Nth address position of the position storage memory M5, and the process proceeds to Step P35 described above. On the other hand, if no in step P32, the process returns to step P31.

  Next, it is determined whether or not the regular paper switch 29 is OFF in step P35 described above. If yes, 1 is added to the count value M of the memory M11 and overwritten in step P36. Control goes to step P42.

  Next, in step P37, the count value is read from the current print number counting counter 34 and stored in the Mth address position of the main printing stop position storage memory M4. Then, in step P38, the print sheet count of the web rotary press is counted. It is determined whether or not the output of the sensor 35 is ON. If yes, the process proceeds to step P236, which will be described later. If NO, it is determined in step P39 whether the regular paper switch 29 is ON.

  Next, if yes in step P39, 1 is added to the count value N of the memory M12 in step P40 and overwritten. Then, in step P41, the count value is read from the counter 34 for counting the current number of printed sheets, and the main printing is resumed. The data is stored in the Nth address position of the position storage memory M5. On the other hand, if no in step P39, the process returns to step P38.

  Next, in step P42, it is determined whether or not the target print number setting device 33 has been re-inputted. If yes, the setting value of the target print number setting device 33 is read in step P43, and the target print number setting device is stored. The data is stored in the memory M2 and the process returns to Step P12. If not, the process returns to Step P12.

  In the present embodiment, the routine of Step P28 to Step P34 and the routine of Step P35 to Step P43 described above have been described in time series. However, as in Embodiment 1, at least one of these routines is performed in an unsteady manner. The

  According to the above operation flow, when the paper loss signal is turned ON and the normal paper switch 29 is turned OFF based on the count value of the current print sheet count counter 34, the main printing stop position is stored and the paper loss signal When is turned off and the regular paper switch 29 is turned on, the main printing restart position is stored. When the target print number setting device 33 is re-input, the target print number setting unit 33 stores the target print number in the target print number storage memory M2.

  Next, the count value is read from the current print number counting counter 34 in step P44 and stored in the current print number storage memory M13 of the web rotary press. Then, in step P45, the count value MM of the memory M14 is set. After 1 is overwritten, the count value MM is read from the memory M14 in step P46. In step P47, the count value M is read from the memory M11.

  Next, in step P48, it is determined whether or not the count value MM> the count value M. If yes, the process proceeds to step P65 described later. If no, the count value MM is read from the memory M14 in step P49.

  Next, in step P50, the MMth final printing stop position is read from the MMth address position of the main printing stop position storage memory M4 and stored in the memory M15. Then, in step P51, the reject device 40A on the A side from the memory M16 is read. (The number of sheets from the web-fed rotary printing press to the A-side reject device 40A).

  Next, in step P52, the number of sheets up to the A-side reject device 40A is added to the MM-th final printing stop position to calculate the A-side MM-th reject start position, which is stored in the memory M17, and then in step P53. The current number of printed sheets of the web rotary press is read from the memory M13.

  Next, in step P54, it is determined whether or not the MM-th reject start position on the A side is the current number of pages printed on the web rotary press. If yes, a reject signal is output to the A-side reject device 40A in step P55. Then, the process proceeds to step P56, which will be described later. On the other hand, if no, the process directly proceeds to step P56.

  Next, after reading the count value MM from the memory M14 in step P56 described above, in step P57, the MMth final printing stop position is read from the MMth address position of the final printing stop position storage memory M4, and the memory M15. To remember.

  Next, after reading the number of sheets from the memory M18 to the B-side reject device 40B (the number of sheets from the web rotary press to the B-side reject device 40B) in Step P58, the MMth final printing stop position in Step P59. Is added to the B side reject device 40B, and the B side MMth reject start position is calculated and stored in the memory M19.

  Next, in step P60, the current number of pages printed on the web rotary press is read from the memory M13, and in step P61, whether or not the MM-th reject start position on the B side is the current number of pages printed on the web rotary press. to decide.

  Next, if yes in step P61, a reject signal is output to the B-side reject device 40B in step P62, and the process proceeds to step P63 described later, whereas if no, the process immediately proceeds to step 63.

  Next, after reading the count value MM from the memory M14 in step P63 described above, 1 is added to the count value MM in the memory M14 and overwritten in step P64, and the process returns to step P46.

  Next, after overwriting 1 in the count value NN of the memory M20 in Step P65 described above, the count value NN is read from the memory M20 in Step P66. In step P67, the count value N is read from the memory M12.

  Next, in step P68, it is determined whether or not the count value NN> the count value N. If yes, the process proceeds to step P85 described later. If no, the count value NN is read from the memory M20 in step P69.

  Next, in step P70, the NNth final printing restart position is read from the NNth address position of the main printing restart position storage memory M5 and stored in the memory M21. Then, in step P71, the reject device 40A on the A side from the memory M16 is read. Read up to.

  Next, in step P72, the number of sheets up to the A-side reject device 40A is added to the NN-th final printing restart position to calculate the A-side NN-th reject completion position, which is stored in the memory M22, and then in step P73. The current number of printed sheets of the web rotary press is read from the memory M13.

  Next, in step P74, it is determined whether or not the NNth rejection completion position on the A side = the current number of printed pages of the web rotary press. If yes, the rejection signal of the rejection signal to the A-side rejection device 40A is determined in step P75. While the output is stopped and the process proceeds to Step P76 described later, if the result is NO, the process immediately proceeds to Step P76.

  Next, after reading the count value NN from the memory M20 in step P76 described above, in step P77, the NNth final printing restart position is read from the NNth address position of the final printing restart position storage memory M5, and the memory M21. To remember.

  Next, in step P78, the number of sheets from the memory M18 to the B-side reject device 40B is read, and in step P79, the number of sheets up to the B-side reject device 40B is added to the NNth final printing restart position. The NNth reject completion position is calculated and stored in the memory M23.

  Next, in step P80, the current number of pages printed on the web rotary press is read from the memory M13, and in step P81, whether or not the NNth reject completion position on the B side is the current number of pages printed on the web rotary press. to decide.

  Next, if yes in Step P81, the output of the reject signal to the B-side reject device 40B is stopped in Step P82 and the process proceeds to Step P83 to be described later. If not, the process proceeds directly to Step 83. To do.

  Next, after reading the count value NN from the memory M20 in the above-described step P83, 1 is added to the count value NN in the memory M20 and overwritten in step P84, and the process returns to step P66.

  According to the above operation flow, the A-side and B-side reject devices 40A and 40B are operated corresponding to the main printing stop position and the main printing resuming position, and the waste paper (scrap paper) can be reliably removed.

  Next, after overwriting 1 in the count value MM of the memory M14 in step P85, the count value MM is read from the memory M14 in step P86. In step P87, the count value M is read from the memory M11.

  Next, in step P88, it is determined whether or not the count value MM> the count value M. If yes, the process proceeds to step P105 described later. If no, the count value MM is read from the memory M14 in step P89.

  Next, in step P90, the MMth final printing stop position is read from the MMth address position in the main printing stop position storage memory M4 and stored in the memory M15. Then, in step P91, the discharge conveyor on the A side from the memory M24. The number of sheets up to the paper supply confirmation sensor 39A (the number of sheets from the web rotary printing press to the paper discharge conveyor paper supply confirmation sensor 39A on the A side) is read.

  Next, in step P92, the number of sheets up to the A-side discharge conveyor section paper supply confirmation sensor 39A is added to the MM-th final printing stop position to calculate the A-side MM-th count stop position, and the result is stored in the memory M25. After the storage, in step P93, the current number of printed sheets of the web rotary press is read from the memory M13.

  Next, in step P94, it is determined whether or not the MMth count stop position on the A side = the current number of pages printed by the web rotary press. If yes, the current counter for counting the number of normal sheets on the A side is determined in step P95. While the output of the enable signal to 38A is stopped and the process proceeds to Step P96 described later, if the result is NO, the process immediately proceeds to Step P96.

  Next, after reading the count value MM from the memory M14 in step P96 described above, in step P97, the MMth final printing stop position is read from the MMth address position of the final printing stop position storage memory M4, and the memory M15. To remember.

  Next, in step P98, the number of sheets from the memory M26 to the B side discharge conveyor section paper supply confirmation sensor 39B (the number of sheets from the web rotary press to the B side discharge conveyor section paper supply confirmation sensor 39B) is read. After that, in step P99, the number of sheets up to the B-side paper discharge conveyor section paper supply confirmation sensor 39B is added to the MM-th final printing stop position, and the B-side MM-th count stop position is calculated. Store in M27.

  Next, in step P100, the current number of pages printed on the web rotary press is read from the memory M13, and in step P101, whether or not the MMth count stop position on the B side is the current number of pages printed on the web rotary press. to decide.

  Next, if yes in step P101, the output of the enable signal to the current B sheet count counter 38B on the B side is stopped in step P102, and the process proceeds to step P103 described later. Then, the process proceeds to step 103.

  Next, after reading the count value MM from the memory M14 in step P103 described above, 1 is added to the count value MM in the memory M14 and overwritten in step P104, and the process returns to step P86.

  Next, after overwriting 1 in the count value NN of the memory M20 in Step P105 described above, the count value NN is read from the memory M20 in Step P106. In step P107, the count value N is read from the memory M12.

  Next, in step P108, it is determined whether or not the count value NN> the count value N. If yes, the process proceeds to step P125 described later. If no, the count value NN is read from the memory M20 in step P109.

  Next, in step P110, the NNth final printing restart position is read from the NNth address position in the main printing restart position storage memory M5 and stored in the memory M21. The number of sheets up to the paper supply confirmation sensor 39A is read.

  Next, in step P112, the number of sheets up to the A-side discharge conveyor section paper supply confirmation sensor 39A is added to the NN-th final printing restart position to calculate the NN-th count restart position on the A side, and the result is stored in the memory M28. After the storage, in step P113, the current number of pages printed by the web rotary press is read from the memory M13.

  Next, in step P114, it is determined whether or not the NNth count restart position on the A side = the current number of pages printed by the web rotary press. If yes, the current counter for counting the number of normal sheets on the A side is determined in step P115. The enable signal is output to 38A and the process proceeds to step P116, which will be described later. On the other hand, if no, the process proceeds to step P116.

  Next, after reading the count value NN from the memory M20 in step P116 described above, in step P117, the NNth final printing restart position is read from the NNth address position of the final printing restart position storage memory M5, and the memory M21. To remember.

  Next, in step P118, the number of sheets from the memory M26 to the B-side discharge conveyor section paper supply confirmation sensor 39B is read, and then in step P119, the B-side discharge conveyor section sheet is moved to the NNth final printing restart position. The number up to the supply confirmation sensor 39B is added, and the NNth count restart position on the B side is calculated and stored in the memory M29.

  Next, in step P120, the current number of pages printed on the web rotary press is read from the memory M13, and in step P121, whether or not the NNth count restart position on the B side is the current number of pages printed on the web rotary press. to decide.

  Next, if yes in step P121, an enable signal is output to the current normal sheet count counter 38B on the B side in step P122 and the process proceeds to step P123 described later. 123.

  Next, after reading the count value NN from the memory M20 in step P123 described above, 1 is added to the count value NN in the memory M20 and overwritten in step P124, and the process returns to step P106.

  According to the operation flow described above, the current normal sheet number counting counters 38A and 38B on the A side and the B side are operated corresponding to the final printing stop position and the final printing restart position, and the number of normal sheets can be accurately counted.

  Next, after the data on whether or not the same picture is read from the memory M1 in Step P125 described above, it is determined whether or not the data on whether or not the same picture is 1 in Step P126. The count value is read from the current sheet count counter 38A and stored in the memory M30.

  Next, in step P128, the count value is read from the B-side current sheet count counter 38B and stored in the memory M31. Then, in step P129, the count value of the A-side correct sheet count counter 38A is set. The count value of the current B sheet count counter 38B on the B side is added to calculate the current total sheet count and store it in the memory M9.

  Next, after reading the target print number from the memory M2 in step P130, the target total print number is calculated by multiplying the target print number by 2 in step P131 and stored in the memory M10.

  Next, in step P132, it is determined whether or not the current total number of regular sheets ≧ the target total number of printed sheets. If yes, the process proceeds to step P332, which will be described later. If not, the process returns to step P12.

  Next, in step P133, the count value is read from the current sheet count counter 38A on the A side and stored in the memory M30. Then, in step P134, the count is counted from the current sheet count counter 38B on the B side. The value is read and stored in the memory M31.

  Next, in step P135, it is determined whether or not the count value of the current sheet count counter on the A side ≦ the count value of the present sheet count counter on the B side. If yes, the memory is determined in step P136. While reading the target print number from M2, if not, the process proceeds to Step P138 described later.

  Next, in step P137, it is determined whether or not the count value of the current sheet count counter on the A side is equal to the target print number. If yes, the process proceeds to step P332, which will be described later. Return to.

  Next, after the target number of prints is read from the memory M2 in step P138, it is determined in step P139 whether the current count value of the B-side counter for counting the normal sheet number = the target number of prints. If there is, the process proceeds to Step P332, which will be described later. If not, the process returns to Step P12. Note that the determination of the completion of printing in the case of the same pattern is (current total number of printed sheets ≧ target total number of printed sheets). In this case, the total number of printed sheets is always an even number. In some cases, the count value of the current counter for counting the number of normal sheets is an even number and the other is an odd number. In this case, printing is completed when (current total number of printed sheets = target total number of printed sheets + 1). Because it becomes.

  With the above operation flow, in the case of the same pattern, when the total number of regular sheets discharged to the A-side and B-side discharge conveyors reaches the required number or more, the printing on the web rotary press 100 is terminated, If they are not the same pattern, printing of the web rotary press 100 is terminated when the number of sheets discharged to the paper discharge conveyor with the smaller number of sheets discharged reaches the required number.

  In step P140 described above, the count value is read from the counter 34 for counting the current number of printed sheets and stored in the memory M13 for storing the number of prints of the current web rotary press. Then, in step P141, the count value MM of the memory M14 is set to 1. Is overwritten, the count value MM is read from the memory M14 in step P142. In step P143, the count value M is read from the memory M11.

  Next, in step P144, it is determined whether or not the count value MM> the count value M. If yes, the process proceeds to step P161 described later. If no, the count value MM is read from the memory M14 in step P145.

  Next, in step P146, the MMth final printing stop position is read from the MMth address position in the main printing stop position storage memory M4 and stored in the memory M15. Then, in step P147, the reject device 40A on the A side from the memory M16 is read. Read up to.

  Next, in step P148, the number of sheets up to the A-side reject device 40A is added to the MM-th final printing stop position to calculate the A-side MM-th reject start position, which is stored in the memory M17, and then in step P149. The current number of printed sheets of the web rotary press is read from the memory M13.

  Next, in step P150, it is determined whether or not the MM-th reject start position on the A side is the current number of printed sheets on the web rotary press. If yes, a reject signal is output to the A-side reject device 40A in step P151. Then, the process proceeds to step P152, which will be described later. On the other hand, if no, the process directly proceeds to step P152.

  Next, after reading the count value MM from the memory M14 in the above-described step P152, in step P153, the MMth final printing stop position is read from the MMth address position of the final printing stop position storage memory M4, and the memory M15. To remember.

  Next, in step P154, the number of sheets from the memory M18 to the B-side reject device 40B is read, and then in step P155, the number of sheets up to the B-side reject device 40B is added to the MMth final printing stop position. The MM-th reject start position is calculated and stored in the memory M19.

  Next, in step P156, the current number of pages printed on the web rotary press is read from the memory M13. In step P157, whether or not the MM-th reject start position on the B side is the current number of pages printed on the web rotary press. to decide.

  Next, if yes in Step P157, a reject signal is output to the B-side reject device 40B in Step P158 and the process proceeds to Step P159 described later, while if not, the process immediately proceeds to Step 159.

  Next, after reading the count value MM from the memory M14 in step P159 described above, 1 is added to the count value MM in the memory M14 and overwritten in step P160, and the process returns to step P142.

  Next, after overwriting 1 in the count value NN of the memory M20 in Step P161 described above, the count value NN is read from the memory M20 in Step P162. In step P163, the count value N is read from the memory M12.

  Next, in step P164, it is determined whether or not the count value NN> the count value N. If yes, the process proceeds to step P181 described later. If no, the count value NN is read from the memory M20 in step P165.

  Next, in step P166, the NNth final printing restart position is read from the NNth address position of the final printing restart position storage memory M5 and stored in the memory M21. Then, in step P167, the A side reject device 40A is read from the memory M16. Read up to.

  Next, in step P168, the number of sheets up to the A-side reject device 40A is added to the NN-th final printing restart position to calculate the NN-th reject completion position on the A side and stored in the memory M22. Then, in step P169 The current number of printed sheets of the web rotary press is read from the memory M13.

  Next, in step P170, it is determined whether or not the NNth rejection completion position on the A side = the current number of printed pages of the web rotary press. If yes, the rejection signal of the rejection signal to the A-side rejection device 40A is determined in step P171. While the output is stopped and the process proceeds to Step P172, which will be described later, if the result is NO, the process immediately proceeds to Step P172.

  Next, after reading the count value NN from the memory M20 in the above-described step P172, in step P173, the NNth final printing restart position is read from the NNth address position of the final printing restart position storage memory M5, and the memory M21. To remember.

  Next, in step P174, the number of sheets from the memory M18 to the B-side reject device 40B is read, and in step P175, the number of sheets up to the B-side reject device 40B is added to the NNth final printing restart position. The NNth reject completion position is calculated and stored in the memory M23.

  Next, in step P176, the current number of pages printed by the web rotary press is read from the memory M13. In step P177, whether or not the NNth reject completion position on the B side is the current number of pages printed by the web rotary press. to decide.

  Next, if yes in Step P177, the output of the reject signal to the B-side reject device 40B is stopped in Step P178, and the process proceeds to Step P179 described later. If not, the process immediately proceeds to Step 179. To do.

  Next, after reading the count value NN from the memory M20 in step P179 described above, 1 is added to the count value NN in the memory M20 and overwritten in step P180, and the process returns to step P162.

  According to the above operation flow, the A-side and B-side reject devices 40A and 40B are operated corresponding to the main printing stop position and the main printing resuming position, and the waste paper (scrap paper) can be reliably removed.

  Next, after overwriting 1 in the count value MM of the memory M14 in step P181 described above, the count value MM is read from the memory M14 in step P182. In step P183, the count value M is read from the memory M11.

  Next, in step P184, it is determined whether or not the count value MM> the count value M. If yes, the process proceeds to step P201 described later. If no, the count value MM is read from the memory M14 in step P185.

  Next, in step P186, the MMth final printing stop position is read from the MMth address position of the main printing stop position storage memory M4 and stored in the memory M15. Then, in step P187, the discharge conveyor on the A side from the memory M24 is read. The number of sheets up to the paper supply confirmation sensor 39A is read.

  Next, in step P188, the number of sheets up to the A-side discharge conveyor section paper supply confirmation sensor 39A is added to the MM-th final printing stop position to calculate the A-side MM-th count stop position, and the result is stored in the memory M25. After the storage, in step P189, the current number of pages printed by the web rotary press is read from the memory M13.

  Next, in step P190, it is determined whether or not the MMth count stop position on the A side is the current number of pages printed on the web rotary press. If yes, the current counter for counting the current number of normal sheets on the A side is determined in step P191. The output of the enable signal to 38A is stopped and the process proceeds to Step P192, which will be described later. On the other hand, if not, the process proceeds to Step P192.

  Next, after reading the count value MM from the memory M14 in step P192, the MMth final printing stop position is read from the MMth address position of the final printing stop position storage memory M4 in step P193, and the memory M15. To remember.

  Next, in step P194, the number of sheets from the memory M26 to the B-side discharge conveyor section paper supply confirmation sensor 39B is read, and then in step P195, the B-side discharge conveyor section sheet is moved to the MMth final printing stop position. The number of sheets up to the supply confirmation sensor 39B is added, and the MMth count stop position on the B side is calculated and stored in the memory M27.

  Next, in step P196, the current number of pages printed on the web rotary press is read from the memory M13, and in step P197, the MMth count stop position on the B side = the number of pages printed on the current web rotary press. to decide.

  Next, if yes in step P197, the output of the enable signal to the current normal sheet count counter 38B on the B side is stopped in step P198 and the process proceeds to step P199 described later. The process proceeds to step 199.

  Next, after reading the count value MM from the memory M14 in step P199 described above, 1 is added to the count value MM in the memory M14 and overwritten in step P200, and the process returns to step P182.

  Next, after overwriting 1 in the count value NN of the memory M20 in Step P201 described above, the count value NN is read from the memory M20 in Step P202. In step P203, the count value N is read from the memory M12.

  Next, in step P204, it is determined whether or not the count value NN> the count value N. If yes, the process proceeds to step P221 described later. If no, the count value NN is read from the memory M20 in step P205.

  Next, in step P206, the NNth final printing restart position is read from the NNth address position in the main printing restart position storage memory M5 and stored in the memory M21. The number of sheets up to the paper supply confirmation sensor 39A is read.

  Next, in step P208, the number of sheets up to the A-side discharge conveyor section paper supply confirmation sensor 39A is added to the NN-th final printing restart position to calculate the NN-th count restart position on the A side, and the result is stored in the memory M28. After the storage, in step P209, the current number of pages printed by the web rotary press is read from the memory M13.

  Next, in step P210, it is determined whether or not the NNth count restart position on the A side = the current number of printed pages of the web rotary press. If yes, the current counter for counting the number of normal sheets on the A side is determined in step P211. The enable signal is output to 38A and the process proceeds to step P212, which will be described later.

  Next, after reading the count value NN from the memory M20 in step P212 described above, in step P213, the NNth final printing restart position is read from the NNth address position of the final printing restart position storage memory M5, and the memory M21. To remember.

  Next, in step P214, the number of sheets from the memory M26 to the B-side discharge conveyor section paper supply confirmation sensor 39B is read, and then in step P215, the B-side discharge conveyor section sheet is moved to the NNth final printing restart position. The number up to the supply confirmation sensor 39B is added, and the NNth count restart position on the B side is calculated and stored in the memory M29.

  Next, in step P216, the current number of pages printed on the web rotary press is read from the memory M13, and in step P217, whether or not the NNth count restart position on the B side is the current number of pages printed on the web rotary press. to decide.

  Next, if yes in step P217, an enable signal is output to the current sheet count counter 38B on the B side in step P218 and the process proceeds to step P219 to be described later. 219.

  Next, after reading the count value NN from the memory M20 in step P219 described above, 1 is added to the count value NN in the memory M20 and overwritten in step P220, and the process returns to step P202.

  According to the operation flow described above, the current normal sheet number counting counters 38A and 38B on the A side and the B side are operated corresponding to the final printing stop position and the final printing restart position, and the number of normal sheets can be accurately counted.

  Next, after reading the data indicating whether or not the same pattern is read from the memory M1 in Step P221 described above, it is determined whether or not the data indicating whether or not the same pattern is 1 in Step P222. If yes, the A side is determined in Step P223. The count value is read from the current sheet count counter 38A and stored in the memory M30. If not, the process proceeds to Step P229 described later.

  Next, in step P224, the count value is read from the current regular sheet number counter 38B on the B side and stored in the memory M31. Then, in step P225, the count value of the current regular sheet count counter 38A on the A side is set. The count value of the current B sheet count counter 38B on the B side is added to calculate the current total sheet count and store it in the memory M9.

  Next, after reading the target print number from the memory M2 in step P226, the target total print number is calculated by multiplying the target print number by 2 in step P227 and stored in the memory M10.

  Next, in step P228, it is determined whether or not the current total number of regular sheets ≧ the target total number of printed sheets. If yes, the process proceeds to step P332 described later. If not, the process returns to step P32.

  Next, in step P229, the count value is read from the current sheet count counter 38A on the A side and stored in the memory M30. Then, in step P230, the count is counted from the current sheet count counter 38B on the B side. The value is read and stored in the memory M31.

  Next, in step P231, it is determined whether or not the count value of the current sheet count counter on the A side ≦ the count value of the present sheet count counter on the B side. If yes, the memory is stored in step P232. While reading the target print number from M2, if not, the process proceeds to Step P234 described later.

  Next, in step P233, it is determined whether or not the count value of the current sheet count counter on the A side is equal to the target number of prints. If yes, printing is terminated in step P332, which will be described later. Return to Step P32.

  Next, after reading the target print number from the memory M2 in step P234 described above, it is determined in step P235 whether or not the count value of the current normal sheet number counter on the B side = target print number. If there is, the process proceeds to Step P332, which will be described later. If not, the process returns to Step P32. Note that the determination of the completion of printing in the case of the same pattern is (current total number of printed sheets ≧ target total number of printed sheets). In this case, the total number of printed sheets is always an even number. In some cases, the count value of the current counter for counting the number of normal sheets is an even number and the other is an odd number. In this case, printing is completed when (current total number of printed sheets = target total number of printed sheets + 1). Because it becomes.

  With the above operation flow, in the case of the same pattern, when the total number of regular sheets discharged to the A-side and B-side discharge conveyors reaches the required number or more, the printing on the web rotary press 100 is terminated, If they are not the same pattern, printing of the web rotary press 100 is terminated when the number of sheets discharged to the paper discharge conveyor with the smaller number of sheets discharged reaches the required number.

  Next, the count value is read from the counter 34 for counting the current number of printed sheets in step P236 described above and stored in the memory M13 for storing the number of printed sheets of the current web rotary press, and then the count value MM of the memory M14 is stored in step P237. After overwriting 1, the count value MM is read from the memory M14 in step P238. Next, in step P239, the count value M is read from the memory M11.

  Next, in step P240, it is determined whether or not the count value MM> the count value M. If yes, the process proceeds to step P257 described later. If no, the count value MM is read from the memory M14 in step P241.

  Next, in step P242, the MMth final printing stop position is read from the MMth address position of the main printing stop position storage memory M4 and stored in the memory M15. Then, in step P243, the reject device 40A on the A side from the memory M16 is read. Read up to.

  Next, in step P244, the number of sheets up to the A-side reject device 40A is added to the MM-th final printing stop position to calculate the A-side MM-th reject start position, and the result is stored in the memory M17. Then, in step P245 The current number of printed sheets of the web rotary press is read from the memory M13.

  Next, in step P246, it is determined whether or not the MM-th reject start position on the A side = the current number of printed pages of the web rotary press. If yes, a reject signal is output to the A-side reject device 40A in step P247. Then, the process proceeds to step P248, which will be described later. On the other hand, if no, the process proceeds to step P248.

  Next, after reading the count value MM from the memory M14 in step P248 described above, in step P249, the MMth final printing stop position is read from the MMth address position of the final printing stop position storage memory M4, and the memory M15. To remember.

  Next, in step P250, the number of sheets from the memory M18 to the B-side reject device 40B is read, and in step P251, the number of sheets up to the B-side reject device 40B is added to the MM-th final printing stop position. The MM-th reject start position is calculated and stored in the memory M19.

  Next, in step P252, the current number of pages printed on the web rotary press is read from the memory M13, and in step P253, whether or not the MM-th reject start position on the B side is the current number of pages printed on the web rotary press. to decide.

  Next, if yes in Step P253, a reject signal is output to the B-side reject device 40B in Step P254 and the process proceeds to Step P255 described later, while if not, the process immediately proceeds to Step 255.

  Next, after reading the count value MM from the memory M14 in step P255 described above, 1 is added to the count value MM in the memory M14 and overwritten in step P256, and the process returns to step P238.

  Next, after overwriting 1 in the count value NN of the memory M20 in Step P257 described above, the count value NN is read from the memory M20 in Step P258. In step P259, the count value N is read from the memory M12.

  Next, in step P260, it is determined whether or not the count value NN> the count value N. If yes, the process proceeds to step P277 described later. If no, the count value NN is read from the memory M20 in step P261.

  Next, in step P262, the NNth final printing restart position is read from the NNth address position of the final printing restart position storage memory M5 and stored in the memory M21. Then, in step P263, the rejection apparatus 40A on the A side from the memory M16 is read. Read up to.

  Next, in step P264, the number of sheets up to the A-side rejection device 40A is added to the NNth final printing restart position to calculate the NNth rejection completion position on the A side, and the result is stored in the memory M22. Then, in step P265 The current number of printed sheets of the web rotary press is read from the memory M13.

  Next, in step P266, it is determined whether or not the NNth reject completion position on the A side = the current number of printed sheets on the web rotary press. If yes, a reject signal to the A-side reject device 40A is determined in step P267. The output is stopped and the process proceeds to Step P268, which will be described later.

  Next, after reading the count value NN from the memory M20 in the above-described step P268, in step P269, the NNth final printing restart position is read from the NNth address position of the final printing restart position storage memory M5, and the memory M21. To remember.

  Next, in step P270, the number of sheets from the memory M18 to the B-side reject device 40B is read, and in step P271, the number of sheets up to the B-side reject device 40B is added to the NNth final printing restart position. The NNth reject completion position is calculated and stored in the memory M23.

  Next, in step P272, the current number of pages printed by the web rotary press is read from the memory M13. In step P273, whether or not the NNth reject completion position on the B side is the current number of pages printed by the web rotary press. to decide.

  Next, if yes in Step P273, the output of the reject signal to the B-side reject device 40B is stopped in Step P274 and the process proceeds to Step P275 described later. If not, the process immediately proceeds to Step 275. To do.

  Next, after reading the count value NN from the memory M20 in step P275 described above, 1 is added to the count value NN in the memory M20 and overwritten in step P276, and the process returns to step P258.

  According to the above operation flow, the A-side and B-side reject devices 40A and 40B are operated corresponding to the main printing stop position and the main printing resuming position, and the waste paper (scrap paper) can be reliably removed.

  Next, after overwriting 1 in the count value MM of the memory M14 in step P277 described above, the count value MM is read from the memory M14 in step P278. In step P279, the count value M is read from the memory M11.

  Next, in step P280, it is determined whether or not the count value MM> the count value M. If yes, the process proceeds to step P297 described later. If no, the count value MM is read from the memory M14 in step P281.

  Next, in step P282, the MMth final printing stop position is read from the MMth address position of the main printing stop position storage memory M4 and stored in the memory M15. Then, in step P283, the discharge conveyor on the A side from the memory M24 is read. The number of sheets up to the paper supply confirmation sensor 39A is read.

  Next, in step P284, the number of sheets up to the A-side discharge conveyor section paper supply confirmation sensor 39A is added to the MM-th final printing stop position to calculate the A-side MM-th count stop position, and the result is stored in the memory M25. After the storage, in step P285, the current number of pages printed by the web rotary press is read from the memory M13.

  Next, in step P286, it is determined whether or not the MM-th count stop position on the A side is the current number of pages printed by the web rotary press. If yes, the current counter for counting the number of normal sheets on the A side is determined in step P287. The output of the enable signal to 38A is stopped and the process proceeds to Step P288, which will be described later. On the other hand, if the result is NO, the process immediately proceeds to Step P288.

  Next, after reading the count value MM from the memory M14 in step P288 described above, in step P289, the MMth final printing stop position is read from the MMth address position of the final printing stop position storage memory M4, and the memory M15. To remember.

  Next, in step P290, the number of sheets from the memory M26 to the B-side discharge conveyor section paper supply confirmation sensor 39B is read, and then in step P291, the B-side discharge conveyor section sheet is moved to the MMth final printing stop position. The number of sheets up to the supply confirmation sensor 39B is added, and the MMth count stop position on the B side is calculated and stored in the memory M27.

  Next, in step P292, the current number of pages printed on the web rotary press is read from the memory M13, and then in step P293, whether or not the MMth count stop position on the B side is the current number of pages printed on the web rotary press. to decide.

  Next, if yes in step P293, the output of the enable signal to the current normal sheet count counter 38B on the B side is stopped in step P294 and the process proceeds to step P295 described later. Then, the process proceeds to step 295.

  Next, after reading the count value MM from the memory M14 in step P295 described above, 1 is added to the count value MM in the memory M14 and overwritten in step P296, and the process returns to step P278.

  Next, after overwriting 1 in the count value NN of the memory M20 in Step P297 described above, the count value NN is read from the memory M20 in Step P298. In step P299, the count value N is read from the memory M12.

  Next, in step P300, it is determined whether or not the count value NN> the count value N. If yes, the process proceeds to step P317 described later. If no, the count value NN is read from the memory M20 in step P301.

  Next, in step P302, the NNth final printing restart position is read from the NNth address position of the main printing restart position storage memory M5 and stored in the memory M21. The number of sheets up to the paper supply confirmation sensor 39A is read.

  Next, in step P304, the number of sheets up to the A-side discharge conveyor section paper supply confirmation sensor 39A is added to the NN-th final printing restart position to calculate the NN-th count restart position on the A side, and stored in the memory M28. After the storage, in step P305, the current number of printed sheets of the web rotary press is read from the memory M13.

  Next, in step P306, it is determined whether or not the NNth count restart position on the A side is the current number of pages printed on the web rotary press, and if yes, the current counter for counting the number of normal sheets on the A side is determined in step P307. The enable signal is output to 38A and the process proceeds to step P308, which will be described later.

  Next, after reading the count value NN from the memory M20 in the above-described Step P308, in Step P309, the NNth final printing restart position is read from the NNth address position of the final printing restart position storage memory M5, and the memory M21. To remember.

  Next, in step P310, the number of sheets from the memory M26 to the B-side discharge conveyor section paper supply confirmation sensor 39B is read, and then in step P311 the B-side discharge conveyor section sheet is moved to the NNth final printing restart position. The number up to the supply confirmation sensor 39B is added, and the NNth count restart position on the B side is calculated and stored in the memory M29.

  Next, in step P312, the current number of pages printed on the web rotary press is read from the memory M13, and then in step P313, whether or not the NNth count restart position on the B side is the current number of pages printed on the web rotary press. to decide.

  Next, if yes in step P313, an enable signal is output to the current normal sheet count counter 38B on the B side in step P314 and the process proceeds to step P315 described later. The process moves to 315.

  Next, after reading the count value NN from the memory M20 in Step P315 described above, 1 is added to the count value NN in the memory M20 and overwritten in Step P316, and the process returns to Step P298.

  According to the operation flow described above, the current normal sheet number counting counters 38A and 38B on the A side and the B side are operated corresponding to the final printing stop position and the final printing restart position, and the number of normal sheets can be accurately counted.

  Next, after reading the data indicating whether or not the same pattern is read from the memory M1 in Step P317, it is determined whether or not the data indicating whether or not the same pattern is 1 in Step P318. If yes, the A side is determined in Step P319. The count value is read from the current sheet count counter 38A and stored in the memory M30. If not, the process proceeds to Step P325 described later.

  Next, in step P320, the count value is read from the current regular sheet number counter 38B on the B side and stored in the memory M31. Then, in step P321, the count value of the current regular sheet number count counter 38A on the A side is set. The count value of the current regular sheet count counter 38B on the B side is added to calculate the current total regular sheet count and store it in the memory M9.

  Next, after reading the target print number from the memory M2 in step P322, the target total print number is calculated by multiplying the target print number by 2 in step P323 and stored in the memory M10.

  Next, in step P324, it is determined whether or not the current total number of regular sheets ≧ the target total number of printed sheets. If yes, the process proceeds to step P332 described later. If not, the process returns to step P39.

  Next, in step P325 described above, the count value is read from the A-side current sheet number counting counter 38A and stored in the memory M30. Then, in step P326, the current sheet number counting counter 38B on the B side counts. The value is read and stored in the memory M31.

  Next, in step P327, it is determined whether or not the count value of the current sheet count counter on the A side ≦ the count value of the current sheet count counter on the B side. If yes, the memory in step P328. While reading the target print number from M2, if not, the process proceeds to Step P330 described later.

  Next, in step P329, it is determined whether or not the count value of the current sheet count counter on the A side = the target print number. If yes, the process proceeds to step P332, which will be described later. Return to.

  Next, after reading the target print number from the memory M2 in step P330 described above, it is determined in step P331 whether or not the count value of the current normal sheet number counter on the B side = target print number. If there is, the process proceeds to Step P332, which will be described later. If not, the process returns to Step P39. Note that the determination of the completion of printing in the case of the same pattern is (current total number of printed sheets ≧ target total number of printed sheets). In this case, the total number of printed sheets is always an even number. In some cases, the count value of the current counter for counting the number of normal sheets is an even number and the other is an odd number. In this case, printing is completed when (current total number of printed sheets = target total number of printed sheets + 1). Because it becomes.

  With the above operation flow, in the case of the same pattern, when the total number of regular sheets discharged to the A-side and B-side discharge conveyors reaches the required number or more, the printing on the web rotary press 100 is terminated, If they are not the same pattern, printing of the web rotary press 100 is terminated when the number of sheets discharged to the paper discharge conveyor with the smaller number of sheets discharged reaches the required number.

  Next, after the start command of ink removing is transmitted to the ink film thickness preparation device 120 in the above-described step P332, the movement of the new web roll 202 to the splicing standby position is transmitted to the auto paste device 36 in step P333. A paste preparation start command such as paper edge alignment between the old web roll 201 and the new web roll 202 is transmitted. Then, in step P334, 1 (in operation) is set in the operation status storage memory M36 of the auto paste device. Overwrite.

  Next, after reading the set rotational speed from the rotational speed setter 43 in step P335 and storing it in the previous rotational speed storage memory M37, whether or not a paste preparation completion signal is transmitted from the auto-paste device 36 in step P336. In step P337, 2 (stopped) is overwritten in step P337, and the process proceeds to step P338. If not, the process immediately proceeds to step P338. To do.

  Next, after the previous rotational speed is read from the memory M37 in step P338, the rotational speed correction value at the time of deceleration is read from the memory M38 in step P339. Next, in step P340, the current rotational speed is calculated by subtracting the rotational speed correction value at the time of deceleration from the previous rotational speed, and stored in the memory M39.

  Next, after reading the rotational speed at the time of blanket cleaning from the memory M80 at step P341, it is determined at step P342 whether or not the current rotational speed is smaller than the rotational speed at the time of blanket cleaning. After the rotation speed storage memory M39 is overwritten with the rotation speed at the time of blanket cleaning, the current rotation speed is read from the memory M39 in step P343. If the answer is no, the process proceeds to step P343.

  Next, after overwriting the current rotational speed in the command rotational speed storage memory M81 in step P345, the command rotational speed is output to the driving motor driver 44 in step P346. Next, after the current rotational speed is overwritten in the previous rotational speed storage memory M37 in step P347, it is determined in step P348 whether or not an ink removal completion signal has been transmitted from the ink film thickness creating device 120.

  If yes in step P348, a print stop command is output to each of the printing units 102a to 102d in step P349, while if no, the process returns to step P336.

  Next, in step P350, the previous rotation speed is read from the memory M37, and in step P351, the rotation speed correction value during deceleration is read from the memory M38. Next, in step P352, the current rotational speed is calculated by subtracting the rotational speed correction value at the time of deceleration from the previous rotational speed, and stored in the memory M39.

  Next, after reading the rotational speed at the time of blanket cleaning from the memory M80 at step P353, it is determined at step P354 whether the current rotational speed is smaller than the rotational speed at the time of blanket cleaning. Are read from the memory M39, and the current rotational speed is overwritten in the command rotational speed storage memory M81 in step P356.

  Next, after outputting the command rotational speed to the driving motor driver 44 in step P357, the current rotational speed is overwritten in the previous rotational speed storage memory M37 in step P358, and the process returns to step P350.

  On the other hand, if yes in step P354, the rotational speed at the time of blanket cleaning is read from the memory M80 at step P359, and then the rotational speed at the time of blanket cleaning is overwritten in the current rotational speed storage memory M39 at step P360.

  Next, after reading the current rotational speed from the memory M39 in step P361, the current rotational speed is overwritten in the command rotational speed storage memory M81 in step P362. Next, in step P363, the command rotational speed is output to the driving motor driver 44.

  Next, after a cleaning start command is transmitted to the blanket cleaning devices 121a and 121b in step P364, it is determined whether or not a paste preparation completion signal is transmitted from the auto paste device 36 in step P365. In P366, 2 (stopped) is overwritten in the operation status storage memory M36 of the auto-pasting apparatus, and the process proceeds to Step P367. On the other hand, if No, the process proceeds to Step P367.

  Next, in step P367, it is determined whether or not a cleaning completion signal is transmitted from the blanket cleaning devices 121a and 121b. If yes, whether or not a paste preparation completion signal is transmitted from the auto paste device 36 in step P368. If NO, the process returns to Step P365.

  Next, if yes in step P368, overwrite 2 (stopped) in the operation status storage memory M36 of the auto paste device in step P369, and then read the previous rotational speed from the memory M37 in step P370, If not, the process immediately proceeds to step P370.

  Next, after the rotational speed correction value at deceleration is read from the memory M38 at step P371, the current rotational speed is calculated by subtracting the rotational speed correction value at deceleration from the previous rotational speed at step P372, and the memory Store in M39.

  Next, in step P373, it is determined whether or not the current rotational speed <0. If yes, the current rotational speed storage memory M39 is overwritten with 0 in step P375, and then the current rotational speed is stored in the memory M39 in step P374. If the answer is no, the program immediately proceeds to step 374.

  Next, after overwriting the current rotational speed in the command rotational speed storage memory M81 in step P376, the command rotational speed is output to the driving motor driver 44 in step P377. Next, in step P378, the current rotational speed is overwritten in the previous rotational speed storage memory M37.

  Next, in step P379, after reading the contents of the operation status storage memory M36 of the auto paste device, it is determined in step P380 whether the contents of the operation status storage memory M36 of the auto paste device = 2. If yes, the process proceeds to step P381, which will be described later. If no, the process returns to step P368.

  As a result of the above operation flow, when the current total number of sheets is equal to or greater than the target total number of printed sheets, an ink removal start command is transmitted to the ink film thickness creating device 120, which is an automatic switching device for job switching, and auto A paste preparation start command is transmitted to the paste device 36, and then a cleaning start command is transmitted to the blanket cleaning devices 121a and 121b.

  Next, after the slow rotational speed is read from the memory M82 in step P381, the current rotational speed storage memory M39 is overwritten with the slow rotational speed in step P382. Next, after reading the current rotational speed from the memory M39 in Step P383, the current rotational speed is overwritten in the command rotational speed storage memory M81 in Step P384.

  Next, after the command rotational speed is output to the driving motor driver 44 in step P385, a paste start command is transmitted to the auto paste device 36 in step P386. Next, in step P387, 1 (in operation) is overwritten in the operation state storage memory M36 of the auto-paste apparatus.

  Next, after the current paper width is read from the memory M32 in step P389, a preset start command and the current paper width are transmitted to the web preset device 122 in step P390.

  Next, after 1 (in operation) is overwritten in the operation status storage memory M83 of the web preset device in step P391, a pre-inking preparation start command (point key control device (PQC) is sent to the ink film thickness creating device 120 in step P392. ) Send a preset). Next, in step P393, 1 (in operation) is overwritten in the operation state storage memory M84 of the ink film thickness producing device.

  Next, in step P394, it is determined whether or not a paste completion command has been transmitted from the auto paste device 36. If yes, 2 (stopped) is set in the operation status storage memory M36 of the auto paste device in step P395. On the other hand, if it is not overwritten, the process proceeds to Step P398 described later.

  Next, in step P398 described above, it is determined whether or not a preset completion signal is transmitted from the web preset device 122. If yes, in step P401, 2 is stored in the operation status storage memory M83 of the web preset device (stopped). ) Is overwritten and the process proceeds to step P400, and if not, the process immediately proceeds to step P400.

  Next, in step P400, it is determined whether or not a pre-inking preparation completion signal has been transmitted from the ink film thickness creating apparatus 120. If yes, in step P401, the ink film thickness creating apparatus stores an operation status storage memory M84. 2 (stopped) is overwritten and the process proceeds to step P402. If not, the process immediately proceeds to step P402.

  Next, after reading the contents of the operation status storage memory M36 of the auto paste device in step P402, it is determined in step P403 whether the contents of the operation status storage memory M36 of the auto paste device = 2. If yes, the content of the memory M83 for storing the operation status of the web preset device is read in Step P404, and then the process proceeds to Step P405. If not, the process returns to Step P394.

  Next, in step P405, it is determined whether or not the content of the operation status storage memory of the web preset device = 2. If yes, the process proceeds to step P406. If not, the process returns to step P394.

  Next, in step P406, it is determined whether or not a pre-inking preparation completion signal is transmitted from the ink film thickness creating device 120. If yes, in step P407, the ink film thickness creating device stores the operation status storage memory M84. After overwriting 2 (stopped), the process proceeds to step P410. On the other hand, if no, the process proceeds to step P410.

  Next, after an operation start command is transmitted to the dancer devices 123a and 123b in step P410, a plate change start command is transmitted to the automatic plate changers 124a and 124b in step P411.

  Next, in step P412, it is determined whether or not a pre-inking preparation completion signal is transmitted from the ink film thickness creating device 120. If yes, in step P413, 2 is stored in the operation status storage memory M84 of the ink film thickness creating device. After overwriting (stopped), the process proceeds to step P414. If not, the process immediately proceeds to step P414.

  Next, in step P414, it is determined whether or not a plate change completion signal is transmitted from the automatic plate changers 124a and 124b. If yes, the slow rotational speed is read from the memory M82 in step P415. If not, the process returns to Step P412.

  Next, in step P416, the current rotational speed storage memory M39 is overwritten with the slow rotational speed, and in step P417, the current rotational speed is read from the memory M39. Next, after overwriting the current rotational speed in the command rotational speed storage memory M81 in step P418, the command rotational speed is output to the driving motor driver 44 in step P419.

  Next, in step P420, a paper feed stop command is transmitted to the auto paste device 36 and the infeed device 125, and in step P421, whether or not a pre-inking preparation completion signal is transmitted from the ink film thickness creating device 120 is determined. to decide.

  Next, if yes in Step P421, the operation state storage memory M84 of the ink film thickness creating apparatus is overwritten with 2 (stopped) in Step P422, and then the process proceeds to Step P423. Control goes to step P423.

  Next, in step P423, it is determined whether or not a paper slack removal completion signal is transmitted from the dancer devices 123a and 123b. If yes, an operation end command is transmitted to the dancer devices 123a and 123b in step P424. If not, the process returns to Step P421.

  Next, in step P425, it is determined whether or not a pre-inking preparation completion signal has been transmitted from the ink film thickness creating device 120. If yes, 2 is stored in the operation status storage memory M84 of the ink film thickness creating device in step P426. After overwriting (stopped), the process proceeds to step P427. If not, the process immediately proceeds to step P427.

  Next, after the folding specification is read from the memory M34 in step P427, the folding specification switching start command and folding specification are transmitted to the folding specification switching device 126 in step P428.

  Next, in step P429, it is determined whether or not a pre-inking preparation completion signal has been transmitted from the ink film thickness creating device 120. If yes, 2 is stored in the operation status storage memory M84 of the ink film thickness creating device in step P430. After overwriting (stopped), the process proceeds to step P431. If not, the process immediately proceeds to step P431.

  Next, in step P431, it is determined whether or not a folding specification switching completion signal is transmitted from the folding specification switching device 126. If yes, the process proceeds to step P432, which will be described later. If not, the process returns to step P429. .

  Next, in step P432, it is determined whether or not a pre-inking preparation completion signal has been transmitted from the ink film thickness creating device 120. If yes, in step P433, the ink film thickness creating device stores the operation status storage memory M84. After overwriting 2 (stopped), the process proceeds to step P434. If not, the process proceeds to step P434.

  With the above operation flow, when the current total number of sheets is equal to or greater than the target total number of printed sheets, a paste start command to the auto paste device 36 → preset to the web preset device 122 following the job switching start command described above. It is transmitted in the order of start command → operation start command to dancer devices 123a, 123b → print plate change command to automatic plate change devices 124a, 124b → fold specification switching start command to folding specification change device 126.

  Next, after the temperature rising start command is transmitted to the drying apparatus 103 in Step P434, it is determined whether or not a pre-inking preparation completion signal is transmitted from the ink film thickness creating apparatus 120 in Step P435. In step P436, 2 (stopped) is overwritten in the operation state storage memory M84 of the ink film thickness creating apparatus, and then the process proceeds to step P437. If not, the process directly proceeds to step P437.

  Next, in step P437, it is determined whether or not a temperature raising completion signal has been transmitted from the drying apparatus 103. If yes, whether or not a pre-inking preparation completion signal has been transmitted from the ink film thickness creating apparatus 120 in step P438. If not, the process returns to Step P435.

  Next, if yes in Step P438, the operation state storage memory M84 of the ink film thickness creating apparatus is overwritten with 2 (stopped) in Step P439, and then the process proceeds to Step P440. Control goes to step P440.

  Next, after reading the contents of the operation status storage memory M84 of the ink film thickness creation device in step P440, it is determined in step P441 whether the contents of the operation status storage memory M84 of the ink thickness creation device = 2. If YES, the slow rotational speed is read from the memory M82 in step P442. If NO, the process returns to step P438.

  Next, after overwriting the slow rotational speed in the previous rotational speed storage memory M37 in step P443, the previous rotational speed is read from the memory M37 in step P444. In step P445, the rotational speed correction value at the time of acceleration is read from the memory M89.

  Next, in Step P446, the current rotational speed is calculated by adding the rotational speed correction value at the time of acceleration to the previous rotational speed, and stored in the memory M39. Then, in Step P447, the current rotational speed is stored in the command rotational speed storage memory M81. Override the rotation speed of. Next, in step P448, the command rotational speed is output to the driving motor driver 44.

  Next, in step P449, the current rotation speed is read from the memory M39, and in step P450, the rotation speed at the start of preinking is read from the memory M90. Next, in step P451, it is determined whether or not the current rotational speed> the rotational speed at the start of pre-inking. If yes, the process proceeds to step P453 described later. If not, the previous rotational speed is stored in step P452. The memory M37 is overwritten with the current rotation speed, and the process returns to Step P444.

  Next, after a pre-inking start command is transmitted to the ink film thickness creating device 120 in step P453 described above, the previous rotation speed is read from the memory M37 in step P454. Next, after the rotational speed correction value at the time of acceleration is read from the memory M89 at Step P455, the current rotational speed is calculated by adding the rotational speed correction value at the time of acceleration to the previous rotational speed at Step P456, Store in the memory M39.

  Next, after overwriting the current rotational speed in the command rotational speed storage memory M81 in step P457, the command rotational speed is output to the driving motor driver 44 in step P458. In step P459, the current rotational speed is overwritten in the previous rotational speed storage memory M37.

  Next, in step P460, it is determined whether or not a pre-inking completion signal is transmitted from the ink film thickness creating device 120. If yes, a print start command is output to each of the printing units 102a to 102d in step P461. If not, the process returns to Step P453.

  Next, in step P462, the previous rotational speed is read from the memory M37, and in step P463, the rotational speed correction value at the time of acceleration is read from the memory M89. Next, in step P464, the current rotational speed is calculated by adding the rotational speed correction value at the time of acceleration to the previous rotational speed, and stored in the memory M39.

  Next, in step P465, the set rotational speed is read from the rotational speed setter 43 and stored in the memory M35. Then, in step P466, it is determined whether or not the current rotational speed is smaller than the set rotational speed. If yes, in step P467. While overwriting the current rotational speed in the command rotational speed storage memory M81, if not, the process proceeds to Step P470 described later.

  Next, in step P468, the command rotational speed is output to the driving motor driver 44, and in step P469, the current rotational speed is overwritten in the previous rotational speed storage memory M37, and the process returns to step P462.

  Next, after the set rotational speed is read from the rotational speed setting unit 43 in step P470 and stored in the memory M35, the current rotational speed storage memory M39 is overwritten with the set rotational speed in step P471.

  Next, after reading the current rotational speed from the memory M39 in step P472, the current rotational speed is overwritten in the command rotational speed storage memory M81 in step P473. Next, in step P474, the command rotational speed is output to the driving motor driver 44, and the process returns to step P5.

  As a result of the above operation flow, when the current total number of regular sheets exceeds the target total number of printed sheets, the temperature increase start command to the drying device 103 → the plan to the ink film thickness creation device 120 is continued following the job switching start command described above. The print start commands are transmitted in the order of the king start commands, and then the print start commands to the respective print units 102a to 102d are output.

  Thus, in this embodiment, in the web rotary press 100 that cuts the web with the slitter 109 in the left-right direction, and then discharges the signatures cut in the front-rear direction onto the A-side and B-side delivery conveyors, Count the number of regular sheets discharged on the A-side and B-side delivery conveyors, and if they are the same pattern, the printing will be terminated when the total number of them reaches the required number, and if they are not the same pattern, Printing is terminated when the smaller number of sheets reaches the required number.

  Further, each automatic switching device for setting the setting of the web rotary press in accordance with the next printed matter is automatically operated in response to the print completion signal.

  As a result, the burden on the operator can be reduced by automation, the web rotary press can be stopped as quickly as possible, and the operating rate can be improved by eliminating waste of printing materials as much as possible.

  Note that the present invention is not limited to the above-described embodiments, and when the web is not cut in the left-right direction by the slitter 109 (that is, one web is not arranged in two lines), that is, at the same time on two web-fed rotary presses. The present invention can also be applied when printing the same pattern.

It is a block diagram of the control apparatus of the web rotary press which shows Example 1 of this invention. It is a block diagram of a control device of a web rotary press. It is a block diagram of a stacker and bundler control device. It is a block diagram of a stacker and bundler control device. It is an operation | movement flowchart of the control apparatus of a web rotary press. It is an operation | movement flowchart of the control apparatus of a web rotary press. It is an operation | movement flowchart of the control apparatus of a web rotary press. It is an operation | movement flowchart of the control apparatus of a web rotary press. It is an operation | movement flowchart of the control apparatus of a web rotary press. It is an operation | movement flowchart of the control apparatus of a web rotary press. It is an operation | movement flowchart of the control apparatus of a web rotary press. It is an operation | movement flowchart of the control apparatus of a web rotary press. It is an operation | movement flowchart of the control apparatus of a web rotary press. It is an operation | movement flowchart of the control apparatus of a web rotary press. It is an operation | movement flowchart of the control apparatus of a web rotary press. It is an operation | movement flowchart of the control apparatus of a web rotary press. It is an operation | movement flowchart of the control apparatus of a web rotary press. It is an operation | movement flowchart of the control apparatus of a web rotary press. It is an operation | movement flowchart of the control apparatus of a web rotary press. It is an operation | movement flowchart of a stacker bundler control apparatus. It is an operation | movement flowchart of a stacker bundler control apparatus. It is an operation | movement flowchart of a stacker bundler control apparatus. It is an operation | movement flowchart of a stacker bundler control apparatus. It is an operation | movement flowchart of a stacker bundler control apparatus. It is an operation | movement flowchart of a stacker bundler control apparatus. It is an operation | movement flowchart of a stacker bundler control apparatus. It is an operation | movement flowchart of a stacker bundler control apparatus. It is an operation | movement flowchart of a stacker bundler control apparatus. It is a block diagram of the control apparatus of the web rotary press which shows Example 2 of this invention. It is a block diagram of a control device of a web rotary press. It is a block diagram of the stacker and bundler control device on the A side and B side. It is a block diagram of the stacker and bundler control device on the A side and B side. It is an operation | movement flowchart of the control apparatus of a web rotary press. It is an operation | movement flowchart of the control apparatus of a web rotary press. It is an operation | movement flowchart of the control apparatus of a web rotary press. It is an operation | movement flowchart of the control apparatus of a web rotary press. It is an operation | movement flowchart of the control apparatus of a web rotary press. It is an operation | movement flowchart of the control apparatus of a web rotary press. It is an operation | movement flowchart of the control apparatus of a web rotary press. It is an operation | movement flowchart of the control apparatus of a web rotary press. It is an operation | movement flowchart of the control apparatus of a web rotary press. It is an operation | movement flowchart of the control apparatus of a web rotary press. It is an operation | movement flowchart of the control apparatus of a web rotary press. It is an operation | movement flowchart of the control apparatus of a web rotary press. It is an operation | movement flowchart of the control apparatus of a web rotary press. It is an operation | movement flowchart of the control apparatus of a web rotary press. It is an operation | movement flowchart of the control apparatus of a web rotary press. It is an operation | movement flowchart of the control apparatus of a web rotary press. It is an operation | movement flowchart of the control apparatus of a web rotary press. It is an operation | movement flowchart of the control apparatus of a web rotary press. It is an operation | movement flowchart of the control apparatus of a web rotary press. It is an operation | movement flowchart of the control apparatus of a web rotary press. It is an operation | movement flowchart of the control apparatus of a web rotary press. It is an operation | movement flowchart of the stacker bundler control apparatus of A side and B side. It is an operation | movement flowchart of the stacker bundler control apparatus of A side and B side. It is an operation | movement flowchart of the stacker bundler control apparatus of A side and B side. It is an operation | movement flowchart of the stacker bundler control apparatus of A side and B side. It is an operation | movement flowchart of the stacker bundler control apparatus of A side and B side. It is an operation | movement flowchart of the stacker bundler control apparatus of A side and B side. It is a block diagram of the control apparatus of the web rotary press which shows Example 3 of this invention. It is a block diagram of a control device of a web rotary press. It is a block diagram of a control device of a web rotary press. It is an operation | movement flowchart of the control apparatus of a web rotary press. It is an operation | movement flowchart of the control apparatus of a web rotary press. It is an operation | movement flowchart of the control apparatus of a web rotary press. It is an operation | movement flowchart of the control apparatus of a web rotary press. It is an operation | movement flowchart of the control apparatus of a web rotary press. It is an operation | movement flowchart of the control apparatus of a web rotary press. It is an operation | movement flowchart of the control apparatus of a web rotary press. It is an operation | movement flowchart of the control apparatus of a web rotary press. It is an operation | movement flowchart of the control apparatus of a web rotary press. It is an operation | movement flowchart of the control apparatus of a web rotary press. It is an operation | movement flowchart of the control apparatus of a web rotary press. It is an operation | movement flowchart of the control apparatus of a web rotary press. It is an operation | movement flowchart of the control apparatus of a web rotary press. It is an operation | movement flowchart of the control apparatus of a web rotary press. It is an operation | movement flowchart of the control apparatus of a web rotary press. It is an operation | movement flowchart of the control apparatus of a web rotary press. It is an operation | movement flowchart of the control apparatus of a web rotary press. It is an operation | movement flowchart of the control apparatus of a web rotary press. It is an operation | movement flowchart of the control apparatus of a web rotary press. It is an operation | movement flowchart of the control apparatus of a web rotary press. It is an operation | movement flowchart of the control apparatus of a web rotary press. It is an operation | movement flowchart of the control apparatus of a web rotary press. It is an operation | movement flowchart of the control apparatus of a web rotary press. It is an operation | movement flowchart of the control apparatus of a web rotary press. It is an operation | movement flowchart of the control apparatus of a web rotary press. It is an operation | movement flowchart of the control apparatus of a web rotary press. It is an operation | movement flowchart of the control apparatus of a web rotary press. It is an operation | movement flowchart of the control apparatus of a web rotary press. It is an operation | movement flowchart of the control apparatus of a web rotary press. It is an operation | movement flowchart of the control apparatus of a web rotary press. It is an operation | movement flowchart of the control apparatus of a web rotary press. It is an operation | movement flowchart of the control apparatus of a web rotary press. It is an operation | movement flowchart of the control apparatus of a web rotary press. 1 is a schematic configuration diagram of a web rotary press. FIG. 6 is an explanatory diagram of a sheet feeding device. It is explanatory drawing of a printing unit. It is explanatory drawing of an ink film thickness preparation apparatus (ink supply apparatus). It is explanatory drawing of cam switching. It is explanatory drawing of guide switching. It is explanatory drawing of a slitter. FIG. 3 is a diagram illustrating the relationship between a web-fed rotary printing press and a stacker / bundler. It is explanatory drawing of a rejection apparatus. It is explanatory drawing of the sensor for a small bundle part paper supply confirmation. It is explanatory drawing of a banding (bundling) specification. It is explanatory drawing of a banding (bundling) specification. It is an operation | movement flowchart of a job switching sequence.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Control device of web rotary printing machine 34 Counter for counting the current number of printed pages 35 Sensor for counting the number of printed pages of the web rotary printing press 36 Auto paste device 37 Print quality inspection device 38A Counter for counting the current number of normal paper on the A side 38B B side current sheet count counter 39A A side discharge conveyor section paper supply confirmation sensor 39B B side discharge conveyor section paper supply confirmation sensor 40A, 64A A side reject device 40B, 64B B side Rejecting device 45 Driving motor 47 Origin phase detection sensor 49 Driving clutch 50 Stacker / bundler control device 50A A side stacker / bundler control device 50B B side stacker / bundler control device 62 Current sheet count counter 62A A side Current paper count counter Uncounter 62B Counter for counting the current number of sheets on the B side 63 Sensor for confirming supply of a small bundle of paper 63A Sensor for confirming supply of a small bundle of paper on the A side 63B Sensor for confirming supply of a small bundle of paper on the B side 64 Reject device 100 Winding paper rotary printing machine 101 Paper feeding device 102 (102a to 102d) Printing unit 103 Drying device 104 Cooling device 105 Web pass device 106 Drag device 107 Folding machine 108 Drag roller 109 Slitter 114A, 114B Paper discharge path (paper discharge conveyor)
115A A side stacker and bundler device 115B B side stacker and bundler device 116 band 120 ink film thickness preparation device 121a, 121b blanket cleaning device 122 web preset device 123a, 123b dancer device 124a, 124b automatic plate change device 125 in Feed device 126 Folding specification switching device

Claims (12)

Printing means for printing on a web,
Cutting means for cutting the printed matter printed by the printing means in a direction perpendicular to the conveyance direction of the web;
A web-fed rotary printing press comprising a paper discharge means for discharging the cut printed matter to a post-processing device for further processing;
Comprising a counting means for counting the number of printed matter discharged to the post-processing device,
In response to the signal from the counting means, the printing means stops printing,
A method for switching a state of a web rotary press, wherein at least one of automatic switching devices for automatically switching the state of the web rotary press to the next printing state is automatically operated.   2. The state switching method for a web-fed rotary printing press according to claim 1, wherein the post-processing device is a stacker and bundler device. Printing means for printing on a web,
First cutting means for cutting the printed matter printed by the printing means in a direction parallel to the web transport direction;
A second cutting means for cutting the printed material cut by the first cutting means in a direction perpendicular to the conveyance direction of the web;
Paper discharge means for discharging the printed material cut by the second cutting means to different paper discharge devices,
In a web printing press equipped with
Counting means for counting the number of printed matter discharged to each paper discharge device;
Pattern setting means for setting whether the cut printed material is the same pattern;
With
When the setting of the picture setting means is the same picture, the printing means stops printing based on the total value of the number of printed matter discharged to each paper discharge device,
A method for switching a state of a web rotary press, wherein at least one of automatic switching devices for automatically switching the state of the web rotary press to the next printing state is automatically operated. The web rotary press is
A strip continuous supply means for pasting the strip of the new web roll to the strip of the old web roll and continuously feeding the strip,
Plate changing means for changing the plate supported on the plate cylinder;
Folding machine folding specification switching means for switching the folding machine state according to the next printing folding specification,
With
When switching the state of the web rotary printing press to the next printing state, the automatic switching devices of the strip continuous supply means, the plate changing means, and the folding specification switching means of the folding machine are operated in a predetermined order. The state switching method of a web rotary press according to claim 1 or 3.   4. The automatic switching device is automatically operated when a total value of the number of printed materials discharged to each of the paper discharge devices is equal to or greater than a set required number of prints. A method for switching the state of the web-fed rotary press described in 1.   When the setting of the pattern setting means is not the same pattern, at least one of the automatic switching devices is automatically operated when the number of printed matter discharged to each of the paper discharge devices exceeds the set required number of prints. The method for switching the state of a web rotary press according to claim 3. Printing means for printing on a web,
Cutting means for cutting the printed matter printed by the printing means in a direction perpendicular to the conveyance direction of the web;
A web-fed rotary printing press comprising a paper discharge means for discharging the cut printed matter to a post-processing device for further processing;
Counting means for counting the number of printed matter discharged to the post-processing device;
Control for automatically operating at least one of automatic switching devices for automatically stopping the state of the web-fed rotary printing press to the next printing state while stopping printing of the printing means in response to a signal from the counting means Means,
A state switching device for a web-fed rotary printing press.   8. The state switching device for a web-fed rotary printing press according to claim 7, wherein the post-processing device is a stacker and bundler device. Printing means for printing on a web,
First cutting means for cutting the printed matter printed by the printing means in a direction parallel to the web transport direction;
A second cutting means for cutting the printed material cut by the first cutting means in a direction perpendicular to the conveyance direction of the web;
Paper discharge means for discharging the printed material cut by the second cutting means to different paper discharge devices,
In a web printing press equipped with
Counting means for counting the number of printed matter discharged to each paper discharge device;
Pattern setting means for setting whether the cut printed material is the same pattern;
When the setting of the picture setting means is the same picture, printing of the printing means is stopped based on a total value of the number of printed matter discharged to each paper discharge device, and the state of the web rotary press is changed to the following: Control means for automatically operating at least one of automatic switching devices for automatically switching to a printing state;
A state switching device for a web-fed rotary printing press. The web rotary press is
A strip continuous supply means for pasting the strip of the new web roll to the strip of the old web roll and continuously feeding the strip,
Plate changing means for changing the plate supported on the plate cylinder;
Folding machine folding specification switching means for switching the folding machine state according to the next printing folding specification,
When switching the state of the web rotary printing press to the next printing state, the automatic switching devices of the strip continuous supply means, the plate changing means, and the folding specification switching means of the folding machine are operated in a predetermined order. Control means;
A state switching device for a web-fed rotary printing press according to claim 7 or 9.   The control means automatically operates at least one of the automatic switching devices when the total value of the number of printed materials discharged to the respective paper discharge devices exceeds a set required number of prints. The state switching device for a web-fed rotary printing press according to claim 9.   When the setting of the picture setting means is not the same picture, the control means is configured to output at least one of the automatic switching devices when the number of printed materials discharged to each of the paper discharge devices is equal to or greater than the set required number of prints. 10. The state switching device for a web-fed rotary printing press according to claim 9, wherein the printer is automatically operated.

Images