EP0530612A1 - Side register and overload control in a sheet printing machine - Google Patents

Abstract

A device with which electric energy and data can be transmitted from a fixed machine component (17) to a rotating machine component (16) of a printer is described. The device is particularly suitable for a remote-controllable oblique adjustment of a printing plate of a printing cylinder even when the latter is rotating. <IMAGE>

Description

The invention relates to a device with the features of the preamble of claim 1.

A device with these features is described in DE 36 33 855 C2. This device is used for releasing, adjusting and tensioning a printing plate of a printing press which lies against the circumference of a plate cylinder, as is a preferred field of application of the invention.

In Fig. 5 of this document, the servomotors or the actuator provided for this purpose are connected to a central processing unit by arrows. The text does not show how the connection is made. Presumably, the data and energy can only be transferred there when the plate cylinder is stationary. However, this is disadvantageous because the machine has to be stopped first. After the pressure plate has been adjusted, it must be started up again, and this naturally results in waste.

With regard to the prior art, reference is also made to DE 39 36 446 A1, which describes another preferred area of application of the device according to the invention. There, the pressure plate is fastened to clamping rails arranged in a cylinder pit, of which the front clamping rail can be adjusted separately at both ends and the rear clamping rail parallel to itself, the adjustment of the clamping rails in the circumferential direction of the plate cylinder and to the outside of the pit against spring force he follows. A sensor is already provided there, which senses the clamping of the pressure plate. This document can already The idea can be taken to correct the register while the machine is running. However, how the electrical energy and the data are to be transferred from the machine frame to the plate cylinder is not described there.

Starting from a device with the features of the preamble of claim 1, the invention is therefore based on the object of designing it in such a way that the data and the electrical energy can be transmitted from the machine-fixed component to the rotating component even when the printing press is running. In the preferred field of application for register correction, this should therefore be possible with the printing press running.

The characterizing features of claim 1 serve to solve this problem. Thereafter, it is essential to provide two separate transmission channels, namely one for the data and the other for the energy, or the data and the energy are transmitted in one channel. The energy supplying AC voltage is rectified on the rotating part of the transformer, because the following components require DC voltage. The data are also transmitted contactlessly via AC voltage, possibly via pulses, and are processed in a signal driver and further processed as such.

An important embodiment of the invention is characterized according to claim 2, characterized in that the transformer is designed as a transformer with rotating windings. Here one takes advantage of the fact that the transformer basically transmits electrical AC voltage for both the energy and the data, and this AC voltage or these pulses can be transmitted contactlessly by a transformer are, for this purpose the transformer only has to be formed in two parts such that one part of the transformer is fixed and the other rotates. Regarding this complex of features, we refer as the state of the art to DE-38 39 771 A1, which already describes the basic features of a rotationally symmetrical transformer without, however, indicating that the transformer can be constructed in two parts such that one part rotates and the other stands . However, this principle is also known per se.

With the help of the two-part transformer mentioned, the data and the energy can be transmitted according to the principle of claim 3 or 4, which characterize possible designs for the transmission.

Claims 6 to 10 are directed to preferred configurations of the circuit in the rotating part.

The control unit addressed in claim 6 links the data to one another and stores them. It controls the individual components.

The channel selection mentioned in claim 7 is necessary when using several servomotors, possibly also with one or more sensors (pressure sockets).

The actual value driver with the position indicators according to claims 8, 9 reports the positions of the servomotors to the control unit.

The actual position can be shown in the display in the rotating part according to claim 10 and / or in the machine-fixed Control unit according to this claim. In this respect, data backflow from the rotating part to the machine-fixed part is also provided.

Fig. 1 -

ein Blockschaltbild der wesentlichen Bauelemente einer erfindungsgemäßen Vorrichtung;

Fig. 2 -

ein Prinzipbild des zweiteiligen Transformators, dem auch seine bevorzugte räumliche Anordnung hervorgeht;

Fig. 3 -

ein Schaltbild eines hierbei zum Einsatz kommenden, zweiteiligen Transformators mit rotierender Sekundärwicklung als Übertrager in einer ersten Ausführungsform;

Fig. 4 -

ein Diagramm, wobei über der Zeit die Stromstärke dargestellt ist und woraus die Schachtelung der Leistungsübertragung und der Datenübertragung hervorgeht bei der Anordnung nach Fig. 3;

Fig. 5 -

eine Prinzipdarstellung zur Erläuterung der einkanaligen Übertragung von Energie und Daten mit Hilfe des Transformators nach Fig. 2 (2. Ausführungsform);

Fig. 6 -

ein Diagramm, wobei über der Zeit die frequenzmodulierte Spannung bei der Übertragung nach Fig. 5 dargestellt ist.

The invention is explained in more detail below on the basis of exemplary embodiments, from which further important features result. It shows:

Fig. 1 -

a block diagram of the essential components of a device according to the invention;

Fig. 2 -

a schematic diagram of the two-part transformer, which also shows its preferred spatial arrangement;

Fig. 3 -

a circuit diagram of a two-part transformer used here with rotating secondary winding as a transformer in a first embodiment;

Fig. 4 -

a diagram showing the current strength over time and from which the nesting of the power transmission and the data transmission is evident in the arrangement according to FIG. 3;

Fig. 5 -

a schematic diagram for explaining the single-channel transmission of energy and data using the transformer of FIG. 2 (second embodiment);

Fig. 6 -

a diagram, wherein the frequency-modulated voltage is shown in the transmission of FIG. 5 over time.

First, the principle of a device according to the invention will be explained in more detail with reference to FIG.

A control unit 2 is provided, which may also have a display for the data values and which is connected to a higher-level host control unit 56 of the printing press. It transmits data indicated by pulses 19 to a transmitter 3 via a line 20.

The control unit 2 also transmits electrical energy indicated by an AC voltage symbol 21 to the transmitter 3 via a line 18.

The components of FIG. 2 and the static part of the transmitter 3 are provided in the machine-fixed area 17 of the printing press.

The other components are fastened to a rotating machine component, preferably to a plate cylinder. This rotating area is indicated by item 16. The two areas are separated from one another by a symbolic dividing line 22 in FIG. 1.

The transformer 3 transmits the electrical energy (power) in the direction of the arrow 23 to a rectifier 4 in a contactless manner, as will be explained in more detail below with reference to the following figures. The latter converts the alternating current into direct current.

The transmitter 3 also conducts the data pulses 19, as indicated by the arrow 24, to a signal driver 5, which represents a serial interface. This is also explained in more detail below using the following figures.

A motor driver 8 is supplied with the DC voltage 25 on the output side of the rectifier 4. A control unit 7 including memory is supplied with DC voltage 26 by the rectifier 4. In addition, the control unit 7 receives a reference voltage 27 from the rectifier 4.

The signal driver 5 is connected by means of a data line 28 to the control unit 7, to which a display 6 is also connected.

The control unit 7 is connected to the motor driver 8 via a control line 29 and the motor driver is connected to a channel selection 10 (channel driver) via a further line 30. An actual value driver 9 is connected to the channel selection via a line 31 and this is in turn connected to the control unit 7 via a line 32.

In the exemplary embodiment shown, a sensor (pressure cell) 11 and a number of servomotors 12, 13, 14, 15 and their position detectors 51, 52, 53, 54 are connected to the channel selection 10.

On the input side, the transformer 3 is supplied, for example, by a clocked power supply. The rectifier 4 generates DC voltages at its outputs, namely on the line 26 a DC voltage of 5 V or a DC voltage of 24 V on the line 25.

The control unit 7 controls the functional sequence. For this purpose, the data are sent to him via the signal driver 5. The signals derived therefrom pass through line 29 to the motor driver 8 and from there to the channel selection 10. The motors 12 to 15 are supplied with direct voltage via the lines 25, 30. The actual values, i.e. the approached positions of the motors and also the actual state of the sensor 11 are fed to the channel selection 10.

In the sequential query from the control unit 7, the actual values supplied to the channel selection 10 are supplied to the actual value driver 9 via line 31 and evaluated by the control unit 7 via line 32. They then appear in the display 6 or, via the lines 28, 24, 19, also on the machine-fixed control unit 2. For this purpose, the control unit 7 controls the channel selection 10 with the signal 55 and asks the actual values generated from 11 and 51 accordingly to 54 from.

Fig. 2 shows a structurally preferred embodiment of this two-part transformer. This shows that the (fixed) core is rotationally symmetrical and has a pot shape with an axial projection 42. The primary windings 33, 34 engage in the annular space formed thereby and the rotating secondary winding 35 engages in the gap between the primary windings 33, 34 .

Position 43 indicates the field lines that extend in the air gap.

The rotating secondary winding 35 is fastened to a plate 44 and the axis of rotation is indicated at item 45. (The data transmission channel 24 is not indicated in Fig. 4.)

Fig. 3 shows the circuit diagram of a two-part transformer used here. Its static part is indicated to the left of the dividing line 22 and its rotating part to the right of it. The static part has two primary-side windings 33, 34 which are inductively coupled to at least one secondary-side winding 35 of the rotating part.

A control unit 36 for the transformer and consumer 37 are also indicated in FIG. 3. The essential components of the control unit are an oscillator, a regulation, a control, a driver, a protection circuit and a generator for time windows (data trigger).

The control unit 36 is supplied with the data by the control unit 2 via the line 19. They are then transmitted as shown in FIG. 4.

4 shows the signal received by the secondary winding 35. It can be seen from this that the electrical energy has been transmitted via pulses 39, which are triangular here. Between these pulses there is a window in which no energy is transmitted and the data transmission 24 with data pulses 40 is placed in this window. This is controlled by the control unit 36.

The data are forwarded via the data channel 24 to the signal driver 5, which is opened, for example, only for the pulse gaps. The energy pulses 39 are rectified and the DC voltage supply thereby obtained reaches the consumers 37.

FIG. 6 explains the transmission with the aid of the arrangement according to FIG. 5. It follows that an amplitude-modulated signal 50 is transmitted, the low-frequency part of which results in power 23 (sine part of curve 50) and the high-frequency part 57 transmits the data 24 .

The signal 50 can also be frequency-modulated or phase-modulated.

It can thus be seen that the auxiliary energy and the control signals can be transmitted into the rotating plate cylinder via the two-part transformer. The transformer is wear-free, maintenance-free and transmits the auxiliary energy and the control data to the adjustment unit in the plate cylinder of the press without contact. The contactless transmission results in a considerable reduction in the control signals, so that an uncritical transmission of control signals is made possible. This in turn enables precise and reproducible positioning.

The control unit 2 thus exchanges control data with the control unit 7 via the transmitter 3 and the signal driver 5. This positions the motors 12 - 15 (possibly only one of these motors is provided) via the motor drivers 8 and the channel selection 10. The positioning data of the motors are evaluated by the control unit 7 via the actual value driver 9. The The clamping process is registered by the pressure cell 11 and fed to the control unit 7 via the channel selection 10 and the actual value driver 9. The positioning data are controlled and displayed by the control unit 7 via the display 6.

The energy required for the voltage supply (power supply) of the electrical loads 37 in the rotating part 16 is transmitted by the transformer 3 and processed in the power supply unit 4 and fed to the electrical components 5 - 11, the motors 12 - 15 and the position indicators 51 - 54.

Reference symbol list

1

2nd

Control unit

3rd

Transformer

4th

Rectifier

5

Signal driver

6

display

7

Control unit

8th

Motor driver

9

Actual value driver

10th

Channel selection

11

sensor

12

Servomotor

13

Servomotor

14

Servomotor

15

Servomotor

16

Area, rotating

17th

Area, machine-proof

18th

management

19th

pulse

20th

management

21

symbol

22

line

23

arrow

24th

arrow

25th

Line (DC voltage)

26

Line (DC voltage)

27

Line (reference voltage)

28

Line (data line)

29

management

30th

management

31

management

32

management

33

Winding

34

Winding

35

Winding

36

Control unit

37

consumer

38

39

pulse

40

Data pulse

41

core

42

head Start

43

Field line

44

plate

45

Axis of rotation

46

Winding

47

Winding

48

49

50

signal

51

Position detector

52

Position detector

53

Position detector

54

Position detector

55

Line (signal line)

56

Control unit

57

proportion of

Claims (11)

Device for the transmission of electrical energy and data from a stationary machine component (17) to a rotating machine component (16) of a printing press, in particular for releasing, adjusting and tensioning a printing plate lying against the circumference of a plate cylinder, with a frame-fixed control unit, which with a processing unit that works on at least one electrical consumer, preferably at least one servomotor (12-15), again preferably for a device for register correction, as described in DE 3,936,446 A1, in which the pressure plate is arranged on clamping rails arranged in a cylinder pit is fixed, of which the front clamping rail can be adjusted separately at its two ends and the rear clamping rail parallel to itself, the adjustment of the clamping rails in the circumferential direction of the plate cylinder and to the outside of the pit against spring force and preferably a sensor (11) is provided which senses the clamping of the pressure plate,
characterized by
that for the transmission of the electrical energy and the data a machine-fixed transformer (3) is provided, which supplies the electrical energy supplied to it as alternating voltage contactlessly to a rotating rectifier (4) and which also supplies the data supplied to it as data pulses contactlessly also to a rotating one Signal driver (5) feeds. Device according to claim 1,
characterized by
that the transformer (3) is designed as a machine-fixed part of a two-part transformer, the other part of which is arranged in a rotating manner, the two parts having the inductively coupled primary or secondary windings (33, 34, 35; 46, 47) of the transformer. Device according to claim 2,
characterized by
that the energy transmission takes place in pulses (39), between which there are dead times in which the data transmission (pulses 40) takes place. Device according to claim 2,
characterized by
that a primary winding (46) and a secondary winding (47) of the transformer are provided for the energy transmission and for the data transmission, which transmit a modulated alternating voltage. Device according to one of claims 1 to 4,
characterized by
that the rectifier (4) and the signal driver (5) are connected to a control unit (7) with memory. Device according to claim 5,
characterized by
that at least one motor driver (8) with channel selection (10) is connected to the control unit (7) and to this the servo motor (s) (12-15) and possibly the sensor (11) are connected. Apparatus according to claim 6,
characterized by
that a position indicator (51-54) is connected to each of the motors (12-15). Device according to claim 6 or 7,
characterized by
that at least one actual value driver (9) is connected to the channel selection (10) and is connected to the control unit (7). Device according to one of claims 5 to 8,
characterized by
that a display (6) is connected to the control unit (7) and / or to the control unit (2). Device according to one of claims 1 to 9,
characterized by
that the control unit (7) and the channel selection (10) are directly connected to one another (signal line 55). Device according to one of claims 1 to 9,
characterized by
that the control unit (2) is connected to a control unit (56) of the printing press.

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