JP2003039630A - Variable printing machine - Google Patents

Abstract

PROBLEM TO BE SOLVED: To enable following printing by directly using the printing program of an ordinary variable printing machine. SOLUTION: In a variable printing machine in which printing units 3a and 3b enabling intermittent printing are arranged between synchronously normally and reversely rotatable in-feed rollers 1 and 2 of a pair, a pre-printing position detector for detecting a printing mark such as a mark printed in advance on continuous paper 8 is provided upstream from printing units 3a and 3b, and a compensator device 21a which adjusts the position of the continuous paper between both in-feed rollers corresponding to the detected value of the detector and couples the phases of a pre-printed image and a following-printed image is provided upstream from the printing units and the detector.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a variable printing machine capable of changing the printing top / bottom length of continuous paper, and in particular,
The present invention relates to a variable printing machine that enables additional printing according to the length of a printing surface that has been preprinted.

[0002]

2. Description of the Related Art A variable printing machine is constructed as shown in FIG. 1, and printing units 3a and 3b are provided between a pair of infeed rollers 1 and 2 which can perform normal rotation and reverse rotation synchronously. Are arranged. The printing units 3a and 3b are composed of a plate cylinder 4, a blanket cylinder 5 and an impression cylinder 6, and the peripheral surface of the blanket cylinder 5 has, for example, 1/2
A large diameter portion serving as a printed surface having a circumferential length sa is provided, and the blanket 7 is attached to the peripheral surface of the large diameter portion.

In this variable printing machine, for example, in one printing unit 3a, the plate is transferred from the plate cylinder 4 to the blanket 7 over the circumferential length from its starting end s to b, that is, the vertical length is s. In the case where the printing of -b is repeated on the continuous paper 8 repeatedly in the vertical direction,
While the blanket cylinder 5 continuously rotates, the continuous paper 8 travels forward at a constant speed over the peripheral length sa of the large diameter portion of the blanket cylinder 5 by the action of the infeed rollers 1 and 2.
There is no next blanket 7 and there is a gap between the blanket cylinder 5 and the impression cylinder 6, traveling in the opposite direction by ab for the rotation of the peripheral length as of the small diameter portion, and repeating this in sequence, the blanket cylinder Every 5 rotations, s-on the continuous paper 8
The image of the vertical length b is printed repeatedly.

At this time, the pair of infeed rollers 1,
The rotation control of No. 2 is such that the relationship between the traveling speed and the traveling distance with respect to the rotation of the blanket cylinder 5 of the continuous paper 8 is controlled by a controller (not shown) as shown in FIG.

That is, as shown in FIG. 1, the blanket cylinder 5 is in a state in which the start end s of the large diameter portion of the blanket cylinder 5 faces the impression cylinder 6, and the end a of the large diameter portion thereof faces the impression cylinder 6. The continuous paper 8 travels at a constant speed s−a during that period (constant speed range), and an image having a vertical length s−b is printed on the continuous paper 8 during that time. Then, while the next blanket cylinder 5 rotates by a-s (intermittent region), the continuous paper 8 moves in the reverse direction by a-b, but at this time, in FIG. Run, then run in the opposite direction between cd and then d-b
It is controlled so that the vehicle accelerates in the forward direction between these points, and the above operation is performed again from this point b over the sa of the blanket cylinder 5. As a result, the continuous paper 8 is repeatedly printed with an image having a vertical length of sb according to the movement of the continuous paper 8. In FIG. 2, a point corresponding to the moving distance of the continuous paper 8 is shown on the curve showing the running speed of the continuous paper 8 in correspondence with the reference numeral of the moving distance shown on the vertical axis.

On the other hand, the conventional overprinting printing apparatus is as shown in FIG. 3, in which the preprinted continuous paper 8 is sent out by the infeed roller 10 and the overprinting printing cylinder 11 composed of a plate cylinder and an impression cylinder. A predetermined additional print image is printed at. At the time of top-to-bottom alignment, the register mark A printed on the continuous paper 8 in advance is read by the mark sensor 12, the mark signal from the mark sensor 12 and the rotation speed of the overprinting printing cylinder 11 from the encoder 13 are read. The signal and the tension signal from the tension sensor 14 are input to the controller 15 for calculation, the result is output to the motor driver 16, and the print motor 1
The differential gear 19 interposed in the power transmission system of the main motor 18 and the in-feed roll 10 is controlled by 7 to control the rotational speed of the above-mentioned overprint printing cylinder 11 driven by the main motor 18. This is performed by controlling the rotation speed of the feed roller 10.

[0007]

As described above, when variable printing is performed by the variable printing machine, the continuous paper is accelerated forward by the infeed rollers 1 and 2 → constant forward traveling → deceleration → stop → reverse traveling. ->Stop-> Forward acceleration is repeated, and printing is performed in the constant-velocity region where the vehicle travels at a constant speed forward. When additional printing is performed by this variable printing machine, in the variable printing machine, printing is performed in the constant velocity area of the continuous paper 8 on which printing is performed in the same manner as normal printing. By controlling the rotation, 1
The print length can be tailored to the preprint for each side.

However, in the intermittent area where the phase adjustment is performed, the continuous paper is made to run in the opposite direction and forward again, so that the moving speed of the continuous paper reaches the uniform speed area at the position where the next printing starts from the start edge. , The infeed roller must be controlled and the pattern of running speeds is programmed so, ie as shown in FIG. Therefore, when performing correction for additional printing, the running speed of the infeed roller in this intermittent area must be controlled by removing it from the above program, and the correction value must be added in the intermittent area to control the phase. However, it is difficult to control the control program of the variable printing machine shown in FIG. 2 for phase correction for additional printing.

The present invention has been conceived in view of the above, and an object of the present invention is to provide a variable printing machine capable of performing additional printing by using the control program of a normal variable printing machine as it is. It is what

[0010]

In order to achieve the above object, a variable printing machine according to the present invention is provided with a pair of infeed rollers which can perform forward rotation and reverse rotation in synchronization. A large-diameter portion, which is composed of a printing cylinder and an impression cylinder that are disposed in close proximity to each other with the continuous paper running on both infeed rollers interposed therebetween, and has a large-diameter portion for printing in contact with the continuous paper, and a paper. And at least one set of printing units having a small diameter portion having a predetermined gap in the circumferential direction are disposed between the two infeed rollers while the large diameter portion of the printing cylinder is in contact with the continuous paper. The continuous paper is run at the same speed as the rotation speed of the large diameter section over the continuous paper over the non-image area of the circumference of the large diameter section of the printing cylinder while the small diameter section faces the continuous paper. In a variable printing machine that runs in the opposite direction Provided on the upstream side of the printing unit is a pre-printing position detector that detects a printing mark such as a mark that is printed in advance on continuous paper, on the upstream side of the printing unit, and on the upstream side of the pre-printing position detector. According to the detection value of the pre-printing position detector, the position of the continuous paper between the two infeed rollers is adjusted to provide a compensator device for performing the phase alignment between the pre-printed image and the overprinted printed image. .

In the variable printing machine, another compensator device is provided on the downstream side of the printing unit so as to follow the compensator device on the upstream side and operate in the opposite direction.

[0012]

[Operation] Normal variable printing is performed on the variable printing machine. When performing additional printing with this variable printing machine, the pre-printing position at this time is detected by the pre-printing position detector, and the compensator device is activated based on this detection value, and both infeed rollers are activated. The position of the continuous paper is slightly displaced to the upstream side or the downstream side to adjust the phase of the additional printing with respect to the preprinting.

[0013]

BEST MODE FOR CARRYING OUT THE INVENTION An embodiment of the present invention will be described with reference to FIG. In this embodiment, the variable printing machine shown in FIG. 1 is used, and the same members as those shown in FIG.

The position in the running direction of the continuous paper 8 between the upstream infeed roller 1 and the upstream printing unit 3a and between the downstream infeed roller 2 and the downstream printing unit 3b. First and second compensator devices 21a and 21b for adjusting the temperature are arranged. Further, a mark sensor 22 for reading a pre-printing mark on the continuous paper 8 is provided on the upstream side of the upstream printing unit 3a.

Both compensator devices 21a and 21b have the same structure.
a and 21b are a pair of guide rollers 23a and 23b which are spaced apart from each other in the running direction of the continuous paper 8, and a compensator roller 24 which is vertically movable between the guide rollers 23a and 23b. Compensator driving device 2 for moving the compensator roller 24 in the vertical direction
It consists of 5.

As shown in FIG. 5, the compensator driving device 25 has nut members 27 having screw holes vertically provided at both ends of a support shaft 26 of the compensator roller 24, and the screw shaft is inserted into the screw holes. The screw member 28 is screwed, and the screw shaft 28 is normally or reversely rotated by the motor 30 via the transmission mechanism 29, whereby the nut member 27 is vertically moved, whereby the compensator roller 24 is vertically moved. . Numerals 31a and 31b are limit switches for determining both end positions of the compensator roller 24 in the vertical direction, and are provided in the vertical direction of the nut member 27.

FIG. 6 shows the compensator devices 21a and 21b.
1B shows another example of the compensator driving device 25 of 1b, in which the compensator roller 24 includes a pair of rotating levers 32.
Of the rotary lever 32 is fixed to the rotary shaft 33. And this rotating shaft 3
3 is a drive lever 3 whose tip is fixed to the rotating shaft 33.
4 is rotated by a screw shaft 28 rotated by a drive motor 30, whereby the compensator roller 24 is moved in the vertical direction. 35 is a universal joint.

As shown in FIG. 4, the pair of upstream and downstream compensator devices 21a and 21b are symmetrically driven in the forward and reverse directions by a motor driver 37 controlled by a controller 36. And, for example,
When the compensator roller 24 of the upstream compensator device 21a moves downward, the compensator roller 24 of the downstream compensator device 21b moves upward by the same distance. At this time, the controller 36 includes the drive motors 38a for the infeed rollers 1 and 2,
The rotation speed signal of 38b and the phase signal of the mark sensor 22 are input and calculated, and the result is output to the driver 37.

The plate cylinders 4, 4 of the printing units 3a, 3b have encoders 39 for detecting the rotational speed of the plate cylinders 4, respectively.
a and 39b are provided, and the detected value is the controller 3
It has been entered in 6.

In the above structure, the printing units 3a, 3
While the infeed rollers 1 and 2 rotate in the forward direction over the circumference of the large diameter portion of the blanket cylinder 5 in synchronization with the operation of b, while the small diameter portion of the blanket cylinder 5 faces the impression cylinder 6 thereafter. , The image on the blanket is sequentially overprinted on the preprinted continuous paper 8 by rotating in the opposite direction over the non-image length of the blanket 7. At this time, the infeed rollers 1 and 2 are the blanket cylinder 5
2 in accordance with the circumferential length s-a and the plate length s-b in FIG.
The controller 3 controls the continuous paper 8 to travel in accordance with the speed and the travel distance diagram of the continuous paper 8 as shown in FIG.
Controlled by 6. The tension of the continuous paper 8 at this time is kept constant by both compensator devices 21a and 21b.

In addition to the control for variable printing described above, the phase adjustment with respect to the pre-printed image in the above-mentioned additional printing is performed by a pair of compensator devices 21a, 21a.
21b is operated.

That is, the phase of the preprinted image is detected by the mark sensor 22, and the phase of the plate cylinder 4 and the distance traveled by the continuous paper 8 are detected by the encoders 39a and 39b provided on the plate cylinder 4, respectively. The detection signal is input to the controller 36. In addition, one of the compensator devices 21a is driven by the driver 37 by the correction signal of the controller 36.
The compensator roller 24 of the compensator roller 24 moves downward, and the compensator device 21b of the other compensator roller 24 operates to relax.

At the beginning of printing, the phases of the printing units 3a and 3b are adjusted in advance so that the mark on the pre-printing (printing head) coincides with the printing start point s. When printing is started, as shown in FIG. 2, the continuous paper 8 repeats a cycle of constant speed forward, decelerating forward, stop, reverse, decelerating backward, stop, and speed increasing forward, and reprinting with a vertical length of sb. Printing is repeated.

At this time, the phase shift of the overprinting with respect to the preprinting is caused by the mark sensor 22 provided at a specific position with respect to the printing unit 3a to constantly read the preprinting mark and the mark read by the mark sensor 22. Position is displaced from the positional relationship with the position of the printing unit 3a,
For example, when the position of the mark read by the mark sensor 22 is closer to the printing unit 3a than a predetermined distance, the detection signal is detected by the controller 36.
Immediately, both compensator devices 21a, 21
b operates, the compensator roller 24 on the upstream side moves downward, the compensator roller 24 on the downstream side moves upward,
The continuous paper 8 is registered on the upstream side of the printing units 3a and 3b. This correction is performed regardless of the constant velocity region and the intermittent region in the diagram shown in FIG.

As described above, the mark sensor 22 detects each mark of pre-printing, but when the mark pitch is short, that is, from the encoders 39a and 39b which detect the rotation of the plate cylinder 4 between the marks. If the number of pulses emitted is small and the distance between the marks is printed with a short travel distance, slow the feed speed of the infeed rollers 1 and 2.
On the contrary, when the mark pitch is long, the feeding speed is increased so that the feeding length of the continuous paper 8 is accurately adjusted to one repeat length between marks. This correction is performed during printing in the constant velocity area of sa.

In the above-described embodiment, an example in which a pair of compensator devices 21a and 21b operating in the forward and reverse directions are arranged on both the inlet side and the outlet side of the printing units 3a and 3b of the variable printing machine has been shown. However, the compensator device may be arranged only on the inlet side of the printing unit, and the dancer roller may be arranged on the outlet side instead of the compensator device.

According to this embodiment, the top-bottom adjustment of the additional printing can be performed by one compensator device.

[0028]

According to the present invention, when additional printing is performed by the variable printing machine, the compensator device provided on the inlet side of the printing unit does not control the feeding control of the infeed roller in the variable printing machine. The print position of the additional printing can be adjusted, and the additional printing can be performed by using the feed control program of the infeed roller of the variable printing machine as it is during the additional printing by the variable printing machine. .

Further, by providing the compensator device on both the inlet side and the outlet side of the printing unit so that the respective operations are performed in the opposite directions, continuous paper at the time of printing alignment by the compensator device is provided. Tension fluctuations are reduced and registration is quick and stable.

[Brief description of drawings]

FIG. 1 is a schematic configuration explanatory diagram of a variable printing machine.

FIG. 2 is a diagram showing the relationship between the rotation of a blanket cylinder and the continuous paper traveling distance in a variable printing machine.

FIG. 3 is a schematic configuration explanatory diagram of additional printing.

FIG. 4 is a schematic configuration explanatory view showing an embodiment of a variable printing machine according to the present invention.

FIG. 5 is a perspective view showing a compensator device portion.

FIG. 6 is a perspective view showing another example of the compensator device portion.

[Explanation of symbols]

1, 2, 10 ... Infeed rollers, 3a, 3b ... Printing unit, 4 ... Plate cylinder, 5 ... Blanket cylinder, 6 ... Impression cylinder,
7 ... Blanket, 8 ... Continuous paper, 11 ... Additional printing cylinder,
12, 22 ... Mark sensor, 13, 39a, 39b ... Encoder, 14 ... Tension sensor, 15, 36 ... Controller, 16, 37 ... Motor driver, 17 ... Print motor, 18 ... Main motor, 19 ... Differential gear, 21
a, 21b ... Compensator device, 23a, 23b ... Guide roller, 24 ... Compensator roller, 25 ... Compensator drive device, 26 ... Spindle, 27 ... Nut member,
28 ... Screw shaft, 29 ... Transmission mechanism, 30, 38a, 38b
... Drive motors, 31a, 31b ... Limit switches, 3
2 ... Rotating lever, 33 ... Rotating shaft, 34 ... Driving lever, 3
5 ... Universal joint.

─────────────────────────────────────────────────── ─── Continuation of front page (51) Int.Cl. ⁷ Identification code FI theme code (reference) B41J 15/04 B41F 33/14 K (72) Inventor Takehiro Fujiwara 111 Takatsuno, Oomura, Hiraka-gun, Akita F term in Miya Koshi Information Machine Co., Ltd. (reference) 2C034 AD11 2C058 AB17 AC03 AE04 AE09 AF06 AF15 AF54 GA14 GB04 GB36 GB48 GB53 GD02 GE03 GE29 GF03 2C060 BA01 BC03 BC12 BC22 2C250 EA33 EA34 EB26

Claims (2)

[Claims] 1. A printing cylinder which is arranged in proximity to a pair of infeed rollers which are capable of performing normal rotation and reverse rotation in synchronization, with a continuous paper sheet which is run by the both infeed rollers being sandwiched therebetween. And a pressure drum, and at least a large diameter portion for contacting continuous paper for printing and a small diameter portion having a predetermined gap with the paper are circumferentially provided on the circumferential surface of the printing cylinder. A pair of printing units are arranged, and the infeed rollers described above travel on the continuous paper at the same speed as the rotation speed of the large diameter portion of the printing cylinder while the large diameter portion of the printing cylinder is in contact with the continuous paper, and the small diameter portion In a variable printing machine in which the continuous paper is made to run in the reverse direction over the non-image area of the circumference of the large diameter portion of the printing cylinder while facing the continuous paper, the continuous printing is performed on the upstream side of the printing unit. Printing marks etc. that have been printed on paper beforehand A pre-printing position detector for detecting the mark is provided, and the continuous between both infeed rollers is provided on the upstream side of the printing unit and on the upstream side of the pre-printing position detector according to the detection value of the pre-printing position detector. A variable printing machine comprising a compensator device that adjusts the position of paper to perform phase alignment between a pre-printed image and an additional-printed image. 2. The variable printing machine according to claim 1, wherein another compensator device is provided on the downstream side of the printing unit so as to follow the upstream compensator device and operate in the opposite direction. Characteristic variable printing machine.