EP0531675A1 - Method and device for adjusting ink zone duct keys into their respective positions - Google Patents

Abstract

Adjustable ink keys are adjusted to move associated portions of a doctor blade relative to associated portions of an ink roll of a printing unit. Each portion of the doctor blade is moved into contact with the associated portion of the ink roll. Each portion of the doctor blade is then moved a predetermined amount away from the associated portion of the ink roll after the portion of the doctor blade has moved into contact with the portion of the ink roll. A measured value associated with the position of the associated ink key is stored in memory. The stored measured value is indicative of the position of the associated ink key after the portion of the doctor blade has moved the predetermined amount away from the portion of the ink roll. The stored measured value corresponds to the lithographic zero position of the ink key. The stored measured value of the ink key is modified each time the portion of the doctor blade moves into contact with the ink roll and then moves the predetermined amount away from the ink roll.

Description

The present invention relates to the adjustment of ink fountain keys in an ink fountain of a printing unit in respective positions.

Various methods of adjusting ink fountain keys in an ink fountain of a printing unit are known. In one of these methods, each ink fountain key is moved with an associated servomotor. Each ink fountain key is assigned to part of an ink knife. The parts of the ink knife are assigned to parts of an ink fountain roller and can be positioned so that a gap is formed between the ink fountain roller and the ink knife.

When the ink roller rotates, a thin ink film forms on it. The thickness of the thin ink film formed on the various parts of the ink fountain roller depends on the width of the gap between the parts of the ink knife and the associated parts of the ink fountain roller. The width of the gap varies as a function of the positions of the parts of the ink knife relative to the associated parts of the ink fountain roller. The position of each part of the ink knife relative to its associated part of the ink fountain roller can be changed by adjusting the ink fountain key assigned to the respective part of the ink knife. Thus, the thickness of the thin ink film on the various parts of the ink fountain roller can be changed by adjusting the ink fountain keys.

The ink fountain keys are typically manually adjusted by an operator while the print engine is in a maintenance state. Typically, each inking screw can be turned by manually turning a knurled head or the like. be adjusted. It is also typical that each ink fountain key can be adjusted by activating a two-directional motor that drives the ink fountain key. While previous methods have been reasonably satisfactory, there is a need to improve the ink fountain key adjustment mechanism.

The present invention relates to a new and improved ink fountain key adjustment mechanism for adjusting a plurality of ink fountain key of an ink fountain in a printing press. According to one aspect of the invention, the device comprises a plurality of movable ink fountain keys and a plurality of activatable motors. Each of the activatable motors is assigned to a respective ink zone screw in order to move it when activated. Each ink zone screw is assigned a sensor element and can be moved after it has moved. A memory stores information, ie the target position for each ink fountain key and the target position for each sensor element assigned to a respective ink fountain key. A first activatable device is provided for reading the stored information and for activating the motors for adjusting the ink fountain key to a desired position. A second activatable device is provided for reading commands for actuating each motor to move each ink fountain key in accordance with its stored target position. A device is provided for reading the position of each sensor element assigned to an ink fountain key after activation of the second activatable device and for modifying the stored information of the desired position of each sensor element in accordance with the position of the sensor element after activation of the second activatable device.

According to another aspect of the invention, a device is provided for adjusting a plurality of ink fountain keys of an ink fountain in a printing press. The device comprises an activatable actuator assigned to each ink zone screw, in order to move the respective ink zone screw when activated. A sensor element is provided for detecting the position of the ink fountain key and for giving a corresponding signal. A memory is provided for storing (i) a predetermined target value for each ink fountain key and (ii) the information which is based on a signal given by the sensor element. A control device is provided (i) for activating the actuator in order to move the respective ink fountain key into a target position based on a predetermined target value stored in the memory, (ii) for monitoring the signal given by the sensor element after the ink fountain key has been moved to the target position based on the predetermined target value, and (iii) to modify the information stored in the memory based on the monitored signal from the sensor element. The actuator is then activated to move the respective ink fountain key to a desired position based on the modified information stored in the memory. An enabling device is provided which enables the control device to activate the actuator in order to move the respective ink fountain key and to modify the information stored in the memory.

The invention is preferably applied in lithographic printing machines and is the target position preferably a lithographic zero position for each ink fountain key in an ink fountain. To bring each ink fountain key into its zero lithographic position, it is moved to bring the associated part of an ink knife into contact with the associated part of an ink fountain roller, and then each ink fountain key is moved to move the associated part of the ink knife a predetermined amount away from that position associated part of the ink fountain roller after these parts have been moved into contact with each other. This creates a gap between the respective part of the ink knife and the ink fountain roller. The gap is of such a width that a barely recognizable, thin ink film appears on the outer surface of the ink fountain roller part in question while the ink fountain roller rotates. This position of the ink fountain key is its lithographic zero position.

The ink fountain keys can be set individually or collectively in groups to their lithographic zero position to adjust the various parts of the ink knife relative to the associated parts of the ink fountain roller. A first measured electrical value, which corresponds to the lithographic zero position of each ink fountain key, is stored in a computer. This first measured electrical value of each ink fountain key is modified each time the respective associated ink knife part moves into contact with the associated part of the ink fountain roller and then the predetermined amount away from the ink fountain roller.

All ink fountain keys each have desired positions for a given printing job and are set to these desired positions based on their assigned lithographic zero positions. The lithographic zero position of each ink fountain key acts as one Reference point when adjusting them. For example, a second measured electrical value can be assigned to each ink fountain key and also stored in the computer. The second measured electrical value corresponds to the desired position of the ink fountain key for a given printing job. Since the desired position to which the ink fountain key is set is based on its lithographic zero position, the second measured electrical value is based on the first measured electrical value.

When a particular print job to be performed is selected, a microprocessor reads the first and second measured electrical values stored in the computer. The microprocessor then calculates these two values and generates a control output signal to move the ink fountain key to the desired position at which it is a predetermined amount from its zero lithographic position. The predetermined amount by which the ink fountain key is removed from its lithographic zero position depends on the specific printing work chosen.

If the first measured electrical value corresponding to the lithographic zero position is modified in the manner described above and stored in the computer, then the desired actual position into which the ink fountain key is moved will also be modified the next time it is used certain print work is chosen for execution. The desired actual position of the ink fountain key will be modified because the predetermined distance between the lithographic zero position of the ink fountain key and the desired actual position into which it moved will remain the same. The first measured electrical values are modified for all ink fountain keys and stored in the same way in the computer.

By modifying the first measured electrical values in accordance with the lithographic zero positions of all ink fountain keys and then storing the modified values in the computer memory, there are several advantages. It is an advantage that a common reference, i.e. the lithographic zero positions of the ink fountain keys is intended for control algorithms that try to maintain a preset color in the printing units. It is a further advantage that the ink fountain keys are systematically adjusted to their desired position relative to their lithographic zero position so that there is no need for an operator to adjust or adjust the ink fountain keys based on any subjective perceptions.

Fig. 1

ist ein schematisches Blockdiagramm der vorliegenden Erfindung;

Fig. 2

ist eine bildliche Darstellung eines in dieser Erfindung verwendeten Steuerpults;

Fig. 3

ist eine Detailansicht eines Teils eines Farbmessers in einer beliebigen Position relativ zu einem zugeordneten Teil einer Farbkastenwalze;

Fig. 4

ist eine Ansicht ähnlich der Fig. 3, worin ein gegebenes Teil des Farbmessers mit dem gegebenen Teil der Farbkastenwalze in Kontakt ist;

Fig. 5

ist eine Ansicht ähnlich der Fig. 3, worin das gegebene Teil des Farbmessers ein vorbestimmtes Maß von dem gegebenen Teil der Farbkastenwalze entfernt ist;

Fig. 6 und 7

sind Flußdiagramme, die das Funktionieren der erfindungsgemäßen Einrichtung darstellt.

The following description of the invention will be further clarified to the person skilled in the art on the basis of the attached drawings, explained below.

Fig. 1

Figure 3 is a schematic block diagram of the present invention;

Fig. 2

Figure 3 is a pictorial representation of a control panel used in this invention;

Fig. 3

is a detailed view of a portion of an ink knife in any position relative to an associated portion of an ink fountain roller;

Fig. 4

Figure 3 is a view similar to Figure 3, wherein a given part of the ink knife is in contact with the given part of the ink fountain roller;

Fig. 5

3 is a view similar to FIG. 3, wherein the given Part of the ink knife is a predetermined distance from the given part of the ink fountain roller;

6 and 7

are flow charts illustrating the operation of the device according to the invention.

The present invention relates to a method and a device for adjusting the positions of ink fountain keys in an ink fountain of a printing press. The present invention can be used in printing machines of various designs. The following description is only exemplary of the application of the present invention in a multi-color lithographic printing machine.

Fig. 1 shows a multicolor lithographic printing machine (10) with four printing units 20, 30, 40, 50. Even if four printing units are shown in Fig. 1, it goes without saying that the printing machine 10 can comprise a different number of printing units . The printing units 20, 30, 40, 50 are each equipped with a pair of ink fountains.

Each printing unit comprises an upper and lower plate cylinder (not shown) and a blanket cylinder (not shown) which interacts with the respective upper and lower plate cylinder. The blanket cylinders print on both sides of a web of material passing through the printing unit. It is known that dampening water is applied to every printing plate or plate cylinder. A color box is also assigned to each plate cylinder for supplying ink to the printing plate on the plate cylinder.

As shown in FIG. 1, the printing unit 20 has a pair of ink boxes 25, 26, the printing unit 30 has a pair of ink boxes 35, 36, the printing unit 40 has a pair of ink boxes 45, 46 and the printing unit 50 has a pair Color boxes 55, 56. The color boxes 25, 35, 45, 55, 26, 36, 46, 56 are allocated to respective microprocessors 27, 37, 47, 57, which communicate with respective computer memories 28, 38, 48, 58. Such microprocessors are commercially available and their structure and function are well known in the art. Thus, the microprocessors 27, 37, 47, 57 are not described in detail here.

The control desk 14 shown in FIG. 2 comprises a desk computer 77 which communicates with the distributed microprocessors 27, 37, 47, 57 via a high-speed serial network 79 and has an operator panel display 76. The control panel 14 further includes a sheet inspection area 70 as a support for a printed sheet, which carries an image printed by one or a combination of the printing units 20, 30, 40, 50. The control panel 14 also includes a series of manually operated remote selection switches 72 for controlling the positions of ink fountain keys in a selected ink fountain. The manner of choosing a particular color box is described hereinafter. The row of switches 72 is divided into pairs of switches. Each pair of switches is associated with a respective ink zone screw and a predetermined zone area of the sheet inspection area 70.

The control panel 14 also includes a bar graph display 74 to assist the operator in adjusting ink fountain key to their desired positions. The display panel 74 has a plurality of columns with rows of light emitting diodes ("LEDs"). The number of columns with LED rows corresponds to the number of color zone screws and the number of switch pairs 72. Preferably, the number of color zone screws is thirty six and the number of switch pairs 72 is thirty six, and therefore is Number of LED rows in the display field 74 also thirty six.

The touch panel display 76 serves as a user-activated control of the operation of the printing units 20, 30, 40, 50, including the selection of a color box and the selection of the ink fountain key in this ink fountain for adjusting said ink fountain key. The display panel 76 is electrically connected to the computer 77. This display field 76 displays information from the computer 77 to the operator, and the operator can easily enter information into the computer 77 with the aid of a system software program by touching the display field at a suitable point. Such touch panel displays are well known in the art and are not described in detail herein.

The console computer 77, preferably a Model 286 PC AT, manufactured by Qualogy Corporation, San Jose, California, is electrically connected to the row of switches 72, the display panel 74, and the touch panel display 76. The desk computer 77 and the touch panel display 76 cooperate to produce a number of graphical representations associated with the printing units 20, 30, 40, 50. A monitoring panel 75 for the operator with a number of selector switches is located next to the touch panel display 76.

Each ink fountain has the same structure and the same function. For the sake of simplicity, the structure and function of only the ink fountain 25 is described in detail herein. The ink fountain 25 has an ink fountain roller 21 which extends across the printing unit 20. The articulated ink knife 22 is located on the ink fountain roller 21 and extends across the ink fountain roller 21.

A gap 23 for the ink film is formed between the outer peripheral surface 29 of the ink fountain roller 21 and the lower edge of the ink knife 22. The gap 23 between the ink fountain roller 21 and the ink knife 22 has been shown enlarged for better illustration. The gap 23 can be regulated laterally at various points along the ink fountain roller 21 in order to locally control the amount of ink fed from the ink fountain 25 to the printing cylinders (not shown) of the printing unit 10. The ink knife 22 and ink fountain roller 21 form an ink reservoir 24 in a manner well known in the printing art. Ink flows from the ink reservoir 24 through the gap 23 formed between the outer peripheral surface 29 of the ink fountain roller 21 and the lower edge of the ink knife 22, and an ink film of controlled thickness is formed on the ink fountain roller 21.

A variety of ink flow adjustment mechanisms are mounted laterally at different locations along the ink fountain 25 to press against the ink knife 22 at these locations and to make and adjust the opening of the gap 23 between the ink fountain roller 21 and the ink knife 22 at each of these locations . As shown in FIG. 3, only one ink flow adjustment mechanism, identified by reference number 60, is shown. The ink flow adjustment mechanism 60 comprises an ink zone screw 61 with turns which engage turns in a fixed part of the frame of the ink fountain 25. The inking zone screw has a tip which presses against the assigned part of the ink knife 22 and bends it, as a result of which the gap 23 between the ink knife 22 and the ink fountain roller 21 can be controlled locally. The ink fountain key 61 is driven by a two-way servomotor 62. The motor 62 moves the ink fountain key 61 axially inward and outward.

A potentiometer 63 has a movable arm which is mechanically connected to the ink fountain key 61. The potentiometer has a few external electrical connection points and an internal electrical connection point located between them, as is known. The inner electrical connection point of the potentiometer 63 is mechanically connected to the movable arm of the potentiometer 63. The position of the movable arm of the potentiometer 63 depends on the position of the ink fountain key 61. The potentiometer 63 is activated at its outer electrical connection points so that an electrical signal is generated at its inner electrical connection point, which indicates the position of the ink fountain key 61.

The inner connection point of the potentiometer 63 is electrically connected to a signal line 64. The electrical signal of line 64 is connected to microprocessor 27 as an output signal. The microprocessor 27 generates a control output signal via the signal line 65, which occurs after a preprogrammed process in an internal memory of the microprocessor 27. The electrically activatable motor 62 drives the ink zone screw 61 in accordance with the electrical signal received via the line 65 from the microprocessor (27).

The lithographic zero position of an ink fountain key is the position which an ink fountain key assumes relative to the assigned part of an ink roller when a barely visible thin ink film appears on the lateral surface of this assigned part of the ink roller as it rotates. As an example, only the ink fountain key 61 is shown in FIG. 5 in its lithographic zero position. The gap 23 shown in FIG. 5 between the ink fountain roller 21 and the ink knife 22 is for the better Illustration shown enlarged. The adjustment of the ink fountain key 61 to its lithographic zero position, as shown in FIG. 5, begins from any position, as shown in FIG. 3. If adjustments of ink fountain keys are desired in a particular ink fountain, the operator first selects the ink fountain in which they are located.

In Fig. 6, the process for setting the ink fountain keys in a particular ink fountain to their respective lithographic zero position is shown in a flow chart. As an example, assume that the ink fountain keys in the ink fountain 25 are to be selected. In stage 100, a first menu is displayed on the touch panel display 76. The first menu shows a graphical representation of all ink fountains in all printing units 20, 30, 40, 50. As shown in stage 102, the operator selects one of the ink fountains in order to adjust the ink fountain keys, which is the ink fountain 25 in the present example . The color box 25 is selected by pressing on a touch-sensitive area of the touch panel display 76, whereupon the graphic representation of the color box 25 appears. It is intended to provide a touch sensitive area labeled "SELECT ALL" on the touch panel display 76 so that all color boxes in the printing units 20, 30, 40, 50 can be selected at once by pressure from the operator. If all ink fountains are selected at the same time, all ink fountain keys located in them are also selected for adjustment.

After the ink fountain in which the ink fountain keys are to be adjusted has been selected, a second menu appears on the touch panel display 76, as shown in stage 104. A tactile sensitive area labeled "BEGIN CALIBRATION" appears in the second Touchscreen display menu 76. When the touch sensitive area labeled "BEGIN CALIBRATION" is pressed, as shown in step 106, the console computer 77 transfers information to the microprocessor 27 in the print engine 20, indicating that the ink fountain key in the ink fountain 25 have been selected for adjustment. The microprocessor 27 then uses this information to generate control signals for moving all ink fountain keys assigned to the ink fountain 25 into their respective lithographic zero position. Each of the ink fountain keys located in the ink fountain 25 is adjusted in the same way. For the sake of simplicity, the adjustment of only one ink zone screw 61 in the ink fountain 25 is described in detail below.

With respect to the ink fountain key 61 in the ink fountain 25, as shown in FIG. 3, the microprocessor 27 gives a control signal over line 65 to control the actuation of the motor 62. In step 108 the motor 62 is actuated and the ink fountain key 61 becomes axial adjusted in one direction so that the associated part of the ink knife 22 is moved from the position shown in FIG. 3 to a position shown in FIG. 4, in which this part of the ink knife 22 abuts the assigned part of the ink fountain roller 21.

When the relevant part of the ink knife 22 lies against the assigned part of the ink fountain roller 21, the movement of the ink fountain key 61 stops. In step 110 it is determined whether the ink fountain key 61 has stopped its axial movement. If the determination at step 110 is negative, then the process proceeds to step 112. While the ink fountain key is being adjusted, a tactile area "STOP CALIBRATION" appears on the touch panel display 76 to stop any further adjustment when it is pressed. At step 112, it is determined whether the pressure sensitive area labeled "HALT CALIBRATION" was pressed. If this determination at step 112 is positive, the process returns to the beginning with the first menu shown on the touch panel display 76. If this determination at step 112 is negative, then the process moves to step 108 where the ink fountain key 61 continues to move.

If the determination at step 110 is positive, the process proceeds to step 114. The electrical value at the inner connection point of the potentiometer 63 stops changing when the axial movement of the ink fountain key 61 stops. If the microprocessor 27 determines that the electrical value at the inner connection point of the potentiometer 63 no longer changes, then the process continues in step 114 because the ink fountain key 61 has stopped its movement. After in step 114 the ink fountain key 61 has moved the associated part of the ink knife 22 against the assigned part of the ink fountain roller 21, as shown in FIG. 4, and stops, the control signal coming from the microprocessor 27 via the line 65 controls the motor 62, so that the ink fountain key 61 is moved in the opposite axial direction to move the associated part of the ink knife 22 a predetermined amount away from the associated part of the ink fountain roller 21, as shown in Fig. 5. A value corresponding to the predetermined amount of movement of the ink knife 22 away from the associated part of the ink fountain roller 21 is stored in the memory 28. As mentioned above, the ink fountain key in the position shown in FIG. 5 is in its lithographic zero position.

After the ink fountain key has been set to its lithographic zero position shown in FIG. 5, the electrical signal appearing at this moment from the inner connection point of the potentiometer via line 64 is read by the microprocessor 27 and in the Memory 28 stored as shown in stage 116. This electrical signal value assigned to the ink fountain key 61 remains stored in the memory 28 until the ink fountain key 61 is again set to its lithographic zero position in the manner just described. The electrical signal value stored in the memory 28 and assigned to the ink zone screw 61 can be modified regularly by selecting the ink fountain 25 and then by pressing on the touch-sensitive area marked "BEGIN CALIBRATION" on the touch panel display 76, as described above. The electrical signal value stored in the memory 28 is referred to below as the first measured electrical value.

The microprocessor 27 adjusts the other ink fountain key (not shown) associated with the ink fountain 25 in the same manner as the ink fountain key 61. When all ink fountain keys in the ink fountain 25 are set to their lithographic zero position, the calibration process is complete and a barely visible thin ink film appears on the outer surface of the ink fountain roller 21 as it rotates. After all ink fountain keys in the ink fountain 25 have been set to their lithographic zero position and the electrical signal values at the inner connection points of their assigned potentiometers have been stored in the memory 28, all adjustments of the ink fountain keys for a specific printing work are carried out on the basis of this reference point, i.e. the lithographic zero positions of the ink fountain keys.

In the flowchart shown in Fig. 7, the process to be followed is to select a particular print job and move the ink fountain key to the desired positions corresponding to the print job selected shown. When a particular print job needs to be selected, the operator presses a "PRESET" selector 80 located on the operator monitoring panel 75, as shown in step 200. After pressing the selector 80, a menu appears on the touch panel display 76, as shown in step 202, in which a series of printing jobs is mentioned. Preferably, the number of print jobs appearing on the touch panel display 76 is fifteen. An illuminated position indicator points to a print job appearing on display 76. Then, as shown in step 204, the operator selects the desired print job by pressing a particular tactile area present on the touch panel display 76 to move the illuminated position indicator to a position where it indicates the print job to be selected. When the illuminated position indicator is positioned and points to the desired print job, a tactile sensitive area appearing on the touch panel display 76 labeled "BEGIN PRESET" is depressed as shown in step 206. As soon as this touch-sensitive area labeled "BEGIN PRESET" is pressed, the console computer 77 transmits information to the microprocessors 27, 37, 47, 57 distributed in the printing units 20, 30, 40, 50, which indicates that a specific printing job has been selected . The microprocessors 27, 37, 47, 57 then use this information to adjust all ink fountain keys in all ink fountains of the printing groups 20, 30, 40, 50 on the basis of their lithographic zero positions to their desired positions for the particular print job selected.

Each ink fountain key is moved to its desired position relative to its lithographic zero position in the same way. For the sake of simplicity, only the adjustment of the ink zone screw 61 into its desired one Position described. As mentioned above, the first measured electrical value stored in memory 28 is associated with the zero lithographic position. A second measured electrical value, which is assigned to the position of the ink fountain key 61 desired for a selected printing job, is also stored in the memory 28.

After the microprocessor 27 has received the information from the desk computer 77 for adjusting the inking zone screw 61 in accordance with the selected printing work, the microprocessor 27 reads the first and second measured electrical values associated with the inking zone screw 61 and generates a control output signal for controlling the motor via line 65 62, so that the assigned part of the ink knife 22 is moved relative to the assigned part of the ink fountain roller 21. That is, by operating the motor 62, the ink fountain key 61 is moved to the desired position which is a predetermined amount from the lithographic zero position. The predetermined measure between the desired position and the lithographic zero position of the ink fountain key is based on the second measured electrical value, which in turn is based on the first measured electrical value. Thus, the actual position that the ink fountain key 61 assumes when it is moved to its desired position depends on its lithographic zero position.

From the foregoing description, it should be apparent that the information stored in the memory 28 corresponding to the zero positions of the ink fountain keys in the ink fountain 25 is modified each time the ink fountain keys are set to their lithographic zero position. By modifying this information, stored in the memory 28, of the lithographic zero positions of the ink fountain keys in the ink fountains 25 the reference point changes, according to which the ink fountain keys are adjusted for a specific printing job. If this reference point, according to which the ink fountain keys are adjusted for a specific printing job, is modified in the manner described above, the machine wear or the like, which could lead to inaccuracies in the positions of the ink fountain key and thus to poor print quality, be compensated.

By creating a reference point according to which ink fountain keys are to be set in a color box for selected printing work, and then by modifying the reference point in the manner described above, there are several advantages. It is an advantage that a common reference point for control algorithms is created, which the preset colors of the printing units despite machine wear or the like. should maintain. The common reference point is the lithographic zero position of the ink fountain keys. It is another advantage that the ink fountain keys in a paint box are consequently in their desired positions relative to the reference point, i.e. their lithographic zero position, so that any adjustments of the ink fountain keys based on subjective perceptions by an operator can be dispensed with.

It is conceivable to have a panel of selector switches 78 for selecting the color box intended for the adjustment next to the touch panel display 76. It would also be possible to have a keypad, with which the operator can select the particular color box or boxes in which the ink fountain key adjustment is to take place. It would also be possible to have a combination of selector switches, keypads and / or touch panel displays at the same time.

From the foregoing description of the invention, improvements, changes and modifications may become apparent to those skilled in the art. Such improvements, changes and modifications will fall within the scope of the invention as defined by the appended claims.

REFERENCE SIGN LIST

10th

Printing press

14

Control panel

20th

Printing unit

21

Ink fountain roller

22

Color knife

23

gap

24th

Color reservoir 22

25th

Paint box

26

Paint box

27

microprocessor

28

Computer memory

29

Shell surface of the ink fountain roller 21

30th

Printing unit

35

Paint box

36

Paint box

37

microprocessor

38

Computer memory

40

Printing unit

45

Paint box

46

Paint box

47

microprocessor

48

Computer memory

50

Printing unit

55

Paint box

56

Paint box

57

microprocessor

58

Computer memory

60

Color flow adjustment mechanism

61

Ink fountain key

62

Servomotor

63

Potentiometer / sensor element

64

Signal line

65

Signal line

70

Sheet inspection area

72

Remote selector switch

74

Display field (line diagram)

75

surveillance panel

76

Touch panel display

77

Desk computer

78

Selector switch

79

High speed train network

80

Selector switch

100

Stage in the process

102

Stage in the process

104

Stage in the process

106

Stage in the process

108

Stage in the process

110

Stage in the process

112

Stage in the process

114

Stage in the process

116

Stage in the process

200

Stage in the process

202

Stage in the process

204

Stage in the process

206

Stage in the process

Claims (9)

Device for adjusting ink fountain keys in an ink fountain of a printing press, which has the following features:
a plurality of movable ink fountain keys (61);
a plurality of activatable motors (62), each of said activatable motors being associated with a respective ink fountain key and moving it when activated;
a sensor element (63) assigned to a respective ink zone screw, which is movable after the movement of the respective ink zone screw;
a memory (28, 38, 48, 58) for storing information of a target position for each ink fountain key and a target position for each sensor element associated with the ink fountain key;
a first activatable element (27, 37, 47, 57) for reading the stored information for activating said motors to move the ink fountain keys into their desired position;
a second activatable element (27, 37, 47, 57) for storing instructions for activating each motor to move each ink fountain key in accordance with its stored target position; and
an element (27, 37, 47, 57) for reading the position of each sensor element associated with an ink fountain key after activation of said second activatable element and for modifying the stored information of the target position of each sensor element in accordance with the position of said element Sensor element after activation of said second activatable element. Device according to claim 1,
characterized by
that said sensor element (63) comprises a potentiometer (63) with two outer connection points and an inner connection point, which are located on a mechanical arm connected to the respective ink fountain key, said arm moving and its position after the movement of the ink fountain key varies as a function of the position of the ink fountain key, and wherein the outer terminals of said potentiometer are electrically activated to thereby generate an electrical signal at the inner terminal indicating the position of the ink fountain pen. Device for adjusting a plurality of ink zone screws (61) in an ink fountain (25, 26, 35, 36, 45, 46, 55, 56) of a printing press, which has the following features:
an activatable servomotor (62) which is assigned to each ink fountain key and moves it when activated;
a sensor element (63) for detecting the position of the ink fountain key and for generating a signal indicating this position;
a memory (28, 38, 48, 58) for storing (i) a predetermined target value for each ink fountain key, and (ii) information based on a signal generated by said sensor element;
a control element (27, 37, 47, 57) for (i) activating said servomotor in order to move the respective ink fountain key to a desired position, which is based on said predetermined desired value stored in said memory, (ii) monitoring said signal by said Sensor element after the ink fountain key has moved to said target position based on said predetermined target value, (iii) modifying the information stored in said memory based on said monitored signal from said sensor element, and then to (iv) activating said actuator to move the respective ink fountain key to a desired position based on said modified information stored in said memory;
and enabling means (76) for enabling said control element to activate said servomotor to move the respective ink fountain key and to modify said information stored in said memory. Device according to claim 3,
characterized by
said activatable device (62) includes an activatable motor (62) for each ink fountain key (61), said motor being operatively connected to its respective ink fountain key to move it axially inward and outward. Device according to claim 4,
characterized by
that said sensor element (63) comprises a potentiometer (63) with outer connections and an inner connection which are located on a movable arm which is mechanically connected to the respective ink fountain key, said arm moving after the movement of the ink fountain key and occupies a position that varies as a function of the position of the ink fountain key, and the outer terminals of said potentiometer are electrically activated to thereby provide an electrical signal the inner connector that indicates the position of the ink fountain key. Device according to claim 3,
characterized by
that said memory (28, 38, 48, 58) is a computer memory. Device according to claim 3,
characterized by
that the enabling device (76) comprises a touch panel display (76) mounted on a control panel (14). Device according to claim 7,
characterized by
that said control device (27, 37, 47, 57) comprises a microprocessor which reacts to the actuation of said touch panel display (76) and communicates with said computer memory (28, 38, 48, 58). Procedure for moving parts of a
Ink knife (22) relative to an ink fountain roller (21) of a printing unit (20, 30, 40, 50), which comprises the following stages:
moving each part of the ink knife into contact with the ink fountain roller;
moving each part of the ink knife a predetermined amount away from the ink fountain roller after the ink knife parts have moved into contact with the ink fountain roller;
storing a measured value associated with each part of the ink knife in correspondence with the position of the relevant part of the ink knife after the part has moved a predetermined distance away from the ink fountain roller, the stored value corresponds to the lithographic zero position of the ink knife part, the stored measured value of each part is modified each time the part of the ink knife comes into contact with the ink fountain roller and then moves a predetermined amount away from the ink fountain roller.

Images