EP0696503A2 - Method and ductor drive for feeding ink in the ductor inking device of a printing press - Google Patents

Abstract

The ink is transferred from a box (1) by a rotary roller (2) to the inking roller (4) by way of a lifting roller (3). The roller is carried by two levers (5) coupled together by a shaft (6) extending across the width of the printed sheet. The other ends of the levers are lifted by a smaller roller (7) in contact with the surface of a rotary cam (8). This roller can be displaced from the smaller sector of the cam by a threaded spindle (3) rotated by gearing (11,12) from a stationary positioning motor (10) driven in either direction at constant speed.

Description

The invention relates to a method for supplying ink in the lifter inking unit of a printing press and a corresponding lifter drive according to the preamble of the respective method or device claim.

Lifter inking units are widely used in sheetfed offset presses. Such siphon inking units have an ink fountain roller which interacts with an ink fountain in addition to a metering device, on the surface of which the ink to be printed is applied in the form of a layer of zonally adjustable thickness. A siphoning roller, which oscillates back and forth between the ink fountain roller and a downstream inking roller, usually a friction roller, picks up a color strip of a certain length due to occasional contact with the ink fountain roller and transfers this amount of ink to the inking roller or friction roller upon subsequent contact. Additional, subsequent inking unit rollers result in multiple splitting of the amount of ink supplied by the lifting roller. The ink is then applied to the printing form via the inking rollers placed on the forme cylinder.

After the press has been set up, the ink guide is adjusted in accordance with predetermined target specifications as a rule at a lower printing speed (for example 5,000 sheets / h) than the subsequent production. The production speeds of the high-speed sheetfed offset presses known today can be of the order of magnitude 15,000 sheets / h. In this procedure, typical in printing practice, it is repeatedly found that a coloration set at a low machine speed changes when the printing speed is subsequently increased in such a way that the color densities detectable on the printing sheet, for example the measuring fields of a print control strip, decrease. The printed sheets produced when tuning at a low printing speed thus have a higher color density than those which are then produced at the actual production speed. The effect briefly described here is also called color drop. The reverse effect - increased coloration - occurs with a corresponding reduction in printing speed.

Numerous types of drive for a lifting roller are known from the prior art. The drive of a lifting roller by means of a cam mechanism is known, for example, on the DD 276 455 A1 and the DD 212 475 B1. The curve in the drive of the first-mentioned document is driven by a speed-controllable electric motor, the speed of the electric motor being coupled in terms of control technology to the speed of the printing unit of the machine. The lifter drive according to DD 212 475 B1, which can be temporarily stopped via a locking lever, is used to adjust the lifter cycle to the amount of ink to be supplied.

A purely electronically controlled lifter drive is known, for example, from GB 2 193 926 A. However, this document does not show the kinematics according to which the lifting roller is moved between the ink fountain roller and the downstream inking roller.

A pressure medium-operated lifter drive is also known from US Pat. No. 3,013,489. The lifting roller is pivoted here by means of working cylinders which can be pressurized with pressure medium, the pressure medium being pressurized by a feed pump and being fed to the chambers of the working cylinders by a control slide which is driven in a machine-synchronized manner. Even if you constant Assuming the delivery pressure of the pump, the lifter roller will have kinematics in its movement between the ink fountain roller and the downstream inking roller, which depends on the printing speed. The reason for this is that the control slide is driven in time with the printing speed.

The lifter drives cited above are unable to solve the problem of the ink drop formed, particularly in the case of high-speed sheet-fed offset printing machines. One cause of the ink drop must be seen in particular in the fact that the lifter roller experiences floating on the ink layer of the ink fountain roller when it comes into contact with the ink fountain roller due to a difference in the peripheral speeds. Especially at high printing speeds, however, the times in which the lifting roller is brought into contact with the ink fountain roller are very short. Thus, at high printing speeds, the ink transfer from the ink fountain roller to the lifting roller is getting worse. A comparable process also occurs when the ink is transferred from the siphon roller to the downstream inking roller.

In order to counteract the last-described effect of the lifting of the lifting roller on the ink fountain roller or the downstream inking roller, drives have been known in the past in which the peripheral speed of the lifting roller is synchronized with that of the ink fountain roller or downstream inking roller. Such drives are structurally very complex and still do not solve the problem of ink drop at high printing speeds.

The object of the present invention is therefore to improve a method for supplying ink in the lifter inking unit of a printing press and a corresponding lifter drive in accordance with the preamble of the respective method or device claim in such a way that the transfer of the ink from the ink fountain roller to the inking unit is largely independent of the printing speed and a clearly perceptible drop in color can be counteracted, in particular at very high printing speeds.

This problem is solved by the characterizing features of the process or device claim. Advantageous refinements of the invention result from the subclaims.

According to the invention it is preferably provided that the on and off movement of the lifting roller with respect to the ink fountain roller takes place according to a time function which is independent of the printing speed.

According to the invention it can further be provided that not only the movement of the lifting roller for turning on and off with respect to the ink fountain roller is carried out according to a time function which is independent of the printing speed. It is also preferably possible for the lifter roller to be turned on and off with respect to the downstream inking roller after a time function which is independent of the printing speed of the machine. This variant of the invention also has the advantage that the impacts exerted by the lifting roller on the subsequent inking unit rollers become independent of the printing speed.

The invention makes use of the knowledge that the colors used in offset printing technology have pronounced non-Newtonian properties. Thus, if the lifter roller is always turned on and off by the ink fountain roller after the same time function, there can be no changes in the ink transfer dependent on the printing speed.

The invention is preferably used in an ink fountain roller and lifter drive in which the ink fountain roller is driven in the same time manner at all printing speeds, that is to say in particular rotates constantly at a speed independently of the printing speed. To get more color in at higher print speeds per unit of time To promote the inking unit, the contact angle of the lifting roller on the ink fountain roller is increased with increasing printing speed.

According to a simple embodiment of the invention, the drive for the lifting roller can be such that a cam disc is used which is driven by a speed-controlled electric motor. The speed control upstream of the motor is such that the cam disc runs at a predetermined constant speed which is independent of the printing speed of the machine, when the roller of the bearing lever of the lifting roller running on the cam disc runs over those curve sections which in particular switch on and off the Effect lifting roller on the ink fountain roller. After the lifting roller has been turned on and off, in particular against the ink fountain roller, the cam disk is driven again at a speed which correlates with the printing speed of the machine. The times at which the speed of the control curve is switched from a machine-synchronous to a constant speed value can be achieved, for example, by sensory scanning of the control curve. A corresponding evaluation of an angle sensor attached to the printing press is also possible.

Furthermore, a preferred embodiment of the invention is explained with reference to the drawings. In this exemplary embodiment, a cam disk is used which is driven by the inking unit, that is to say rotates at a speed which depends on the printing speed of the machine. A controllable lifting device ensures that the lifting roller is always turned on and off by the ink fountain roller after the same time function.

Fig. 1

einen erfindungsgemäßen Heberantrieb mit Kurvenscheibe und Schwenkhebel,

Fig. 2+3

die Kurvenscheibe in zwei verschiedenen Winkelstellungen sowie

Fig. 4+5

die Stellung der Kurvenscheibe gemäß den Figuren 2 und 3 im Schnitt.

1 to 5 show:

Fig. 1

a lifter drive according to the invention with cam and swivel lever,

Fig. 2 + 3

the cam in two different angular positions as well

Fig. 4 + 5

the position of the cam according to Figures 2 and 3 in section.

Fig. 1 shows an ink fountain 1 extending over the format width of the printing press, with which a rotatably mounted ink fountain roller 2 interacts. Between the ink fountain roller 2 and a downstream inking roller 4, a lifting roller 3 is mounted to move back and forth. The downstream inking roller 4 can in particular be a friction roller that executes axial traversing movements.

The lifting roller 3 is rotatably supported at its two ends in a pivot lever 5. The two pivot levers 5 are connected to one another by a shaft 6 which extends over the format width and is pivotally mounted on the frame. One end of a swivel lever 5 has, on an extension, a rotatably mounted roller 7, which runs on the outer contour of a control cam 8 which rotates as a function of the printing press speed. The spring 7 is pressed against the outer contour of the control cam 8 by spring means (not shown). The drive of the control cam 8 derived from the printing or inking unit can be such that the control cam 8 rotates once when the printing press makes three single-speed revolutions (lifting stroke 1: 3).

According to FIGS. 1 to 3, the control cam 8 has two radii, the lifting roller 3 on the downstream inking roller 4 is present when the roller 7 runs on the large radius of the cam 8. Accordingly, the lifter roller 3 bears against the ink fountain roller 2 when the roller 7 runs on the smaller radius of the control cam 8.

The swivel lever 5 having the roller 7 is assigned a lifting device 9 in such a way that the roller 7 can be lifted off the outer contour of the control cam 8, so that the lifting roller 3 does not abut the ink fountain roller 2 or the downstream inking roller 4. The lifting device 9 according to the invention thus moves the roller 7 in an area between the small and large radius of the control cam 8.

In one embodiment of the invention, the lifting device 9 according to the invention consists of a servomotor 10 rotating in two directions of rotation, each with a constant speed, which is suspended from the frame. A pinion 11 is attached to the rotor shaft of the servomotor 10 and is designed as a spur gear with straight teeth. This meshes with a second pinion 12 which is attached to the end of a threaded spindle screwed into a thread 14 fixed to the frame. The pinion 12 has a width so that in the intended stroke range of the threaded spindle 13 the pinion 11 always remains in mesh with the pinion 12 with its entire width.

FIGS. 2 and 3 show how the lifting device 9 according to the invention, that is to say in particular the threaded spindle 13 which exerts a stroke, can lift the roller 7 of the one pivot lever 5 from the small radius of the control cam 8 or adjust it again. The control curve 8, which rotates as a function of the printing speed, comes, starting from the situation according to FIG. 1, after about half a revolution with the transition from the large to the small radius in the area of the roll 7. First, the roll 7 then runs on the falling one Outer contour of the control cam 8, so that the lifting roller 3 is turned off by the inking roller 4. Since the threaded spindle 13 to the maximum provided Stroke is extended, the roller 7 does not come to rest on the small radius of the rotating control cam 8, but the pivot lever 5 is locked in such a way that the lifting roller 3 assumes an intermediate position between the ink fountain roller 2 and the inking roller 4.

As shown in FIGS. 4 and 5, two rollers 7, 15 are rotatably arranged parallel to one another at the end of the pivot lever 5, roller 7 running on the control cam 8 and roller 15 being associated with the end of the threaded spindle 13.

After the roller 7 has run out of the large radius of the cam 8 and the pivot lever 5 is locked by placing the roller 15 on the extended end of the threaded spindle 13, the actuator 10 is now controlled so that the threaded spindle 13 is a piece in the thread fixed to the frame 14 is screwed in. As a result, roller 7 comes to rest on the small radius of the control cam 8 and runs there. The lifter roller 3 is now employed on the ink fountain roller 2.

Since it is provided according to the invention to drive the actuator 10 at the intended point in time at a constant speed - regardless of the printing press speed - the positioning movement of the lifting roller 3 against the ink fountain roller 2 is always carried out according to the same time function. The threaded spindle 13 in connection with the thread 14 fixed to the frame and the correspondingly configured actuating drive 10 thus represents a lifting device 9, the working movement of which is always carried out according to the same time function.

After the roller 7 set off on the outer contour with the small radius of the control cam 8 has run through almost the entire contour area with the small radius of the control cam 8, the actuating drive 10 is now driven in the opposite direction of rotation for extending the threaded spindle 13 from the thread 14 fixed to the frame. This causes the roller 7 to reach the contour transition before large radius of the control curve 8 is lifted from the small radius. Here, too, the constant drive speed of the actuator 10 in conjunction with the threaded spindle 13 causes the lifting roller 3 to be switched off again from the ink fountain roller 2 after a time function that is independent of the machine speed and to assume a position for a brief moment in which it is neither on the ink fountain roller 2 still rests on the inking roller 4. Now that the threaded spindle 13 has pivoted the swivel lever 5 into an intermediate position via the roller 15, when the control cam 8 rotates further, the roller 7 runs onto the rising contour of the control cam 8, so that the lifting roller 3 is now set against the inking roller 4. The lifting roller 3 is turned on and off against the inking roller 4 in time with the revolving control cam 8, while the lifting roller 3 is turned on and off against the ink fountain roller 2 by the lifting device 9 described above.

Figures 4 and 5 once again show the positions of the rollers 7, 15 according to Figures 2 and 3 in section. Figure 4 shows that the threaded spindle 13 of the lifting device 9, which acts on the roller 15, the roller 7 is lifted from the small radius of the cam 8. The actuating drive 10 of the lifting device 9 is then actuated so that the roller 7 is brought into contact with the small radius of the control cam 8 via the roller 15. As explained above, the lifter roller 3 is now in contact with the ink fountain roller 2.

Now that the roller 7 has expired almost in the entire area of the small radius of the control cam 8, actuation takes place again in the lifting device 9, so that the threaded spindle 13 lifts the roller 7 from the small radius of the control cam 8 via the roller 15 and into spends the intermediate position described. The lifting roller 3 is now switched off from the ink fountain roller 2 and is placed against the inking roller 4 as soon as the roller 7 runs up from this intermediate position onto the contour of the large radius by further turning of the control cam 8.

The actuator 10 on the lifting device 9 described above is connected to a controller (not shown) which, at the times indicated above, causes pulses to actuate the actuator 10. As has already been mentioned above, the control can be operatively connected to sensors which scan markings on the control curve 8 or the transition of the control curve 8 from the large to the small radius and vice versa. By means of the control it can also be possible to set the triggering times for the lifting device 9 as a function of the printing speed. This can be used, for example, to carry out dead time compensation or to increase the lifting system angle on the ink fountain roller 2 at the printing speed.

Reference list

1

Paint box

2nd

Ink fountain roller

3rd

Lifter roller

4th

Inking roller

5

Swivel lever

6

wave

7

role

8th

Control curve

9

Lifting device

10th

Actuator

11

pinion

12th

pinion

13

Threaded spindle

14

thread

15

role

Claims (7)

Method for supplying ink in the lifter inking unit of a printing press, in particular sheetfed offset printing machine, in which a lifter roller periodically executes a movement between an ink fountain roller and a downstream inking unit roller depending on the printing speed,
characterized,
that the movement of the lifting roller for turning on and off at least one of the two rollers takes place according to a time function which is independent of the printing speed. Method according to claim 1,
characterized by
that the lifting and lowering of the lifting roller on the ink fountain roller takes place after a printing speed-independent time function. Method according to one of claims 1 or 2,
characterized by
that the ink fountain roller is driven in a constant manner at all printing speeds, and that the contact angle of the lifting roller between the on and off at the ink fountain roller is increased with increasing printing speed. Lifter drive for the lifter roller in the lifter inking unit of a printing press, in particular sheetfed offset printing machine, in which a lifter roller is movably mounted between an ink fountain roller and a downstream inking roller and is occasionally alternately brought up against the ink fountain roller and the downstream inking roller by a lifting drive,
characterized by
that the lifter drive (8 to 14) is designed to the lifter roller (3) for turning on and off at least one of the Rolls (2, 4) to impress a movement which takes place according to a time function which is independent of the printing speed. Lifter drive according to claim 4,
characterized by
that the lifter drive (8 to 14) has a roller (7) running on a control cam (8) driven by the printing unit, the control cam (8) having at least two different radii, and that the control cam (8) has a controllable lifting device (10 to 14) is assigned, by means of which the roller (7) can be lifted from a smaller radius of the control curve (8) and brought into a position between two radii of the control curve (8). Lifter drive according to claim 5,
characterized by
that the lifting device (10 to 14) has a threaded spindle (13) screwed into a frame-fixed thread (14) and the threaded spindle (13) can be driven by a controllable actuator (10). Lifter drive according to claim 4,
characterized by
that the lifter roller (3) can be driven via a roller (7) cooperating with a control cam (8), the control cam (8) having an outer contour with at least two different radii, and that the control cam (8) has its own speed-controllable drive can be driven, with this drive the control cam (8) can be driven temporarily both with a speed dependent on the printing press speed and with a predetermined speed independent of the printing press speed.

Images