DE2206497C2 - Control circuit for the dampening unit of an offset rotary printing press - Google Patents

Description

an advantageous implementation of the invention,

An embodiment of the invention is shown in Illustrations are shown and will be described in more detail below with reference to the reference numerals. Show it

Fig. La and Ib a circuit diagram of the control circuit according to the invention;

F i g. 2 shows a graphic representation of the dependency of the control voltage of the control signal generator on its input voltage in the control circuit according to FIG. 1;

F i g. 3 shows a graphic representation of the dependence of the control voltage of FIG Span. *.!. c £ «niwi? -4üs: and

F i g. 4 shows a graphic representation of the control voltage with a greater steepness of the dependence on the Input voltage of the control signal transmitter according to FIG. 2.

Fig. La and Ib show a .Thematic circuit diagram the control circuit for controlling the speed of a plurality of drive motors 10 in the Dampening units of an offset rotary printing press. In the embodiment shown, there are four Dampening units and thus four drive motors 10 provided - the drive of the drive motors 10 takes place via a conventionally constructed control circuit shown essentially in the circuit diagram of FIG. whose control voltage differs from that essentially shown in FIG. la control signal transmitter shown in the circuit diagram 1 is generated.

The signal transmitter for the control signal transmitter 1 consists of a tachometer generator 11 which rotates at the speed of the plate cylinder and emits a direct voltage, the level of which is proportional to the rotational speed of the plate cylinder. This direct voltage forms the input voltage D of the control signal transmitter t; it is divided at the resistors 12, 33 of a voltage conductor and is applied to the slider of a trimming potentiometer 14, which is connected to a first input of a servo amplifier 15. The direct voltage emanating from the voltage divider is applied to a second input of the servo amplifier 15. The servo amplifier 15 is connected to a DC voltage supply 16.

Instead of the tachometer generator 11, the signal generator can also be formed by an auxiliary potentiometer whose grinder is adjusted by a control motor in the main control of the printing machine will.

A servo motor 17 is connected to the output of the servo amplifier 15 and is mechanically coupled to a wiper of the adjustment potentiometer 14 and to a wiper 22 of an input potentiometer 18 of a resistor matrix 19. The resistor matrix 19 is a commercially available component. Adjustable cross connectors 20 therein connect a plurality of vertical rails 20a. electrically connected to the input potentiometer 18 at equal intervals with a corresponding plurality of horizontal rails 20b. which are electrically connected to an output potentiometer 21 at equal intervals. The cross connectors 20 are set so that the output voltage of the resistor matrix 19 between the wiper 22 and a conductor 23 changes in accordance with the function predetermined by the cross connectors 20 with the rotational speed of the plate cylinder. The output voltage between the conductors 22 and 23 increases in accordance with that shown in FIG. 2 graphically represented hyperbolic function asymptotically to This output voltage is the control voltage (SP) of the control signal generator 1, which is fed to the conventional control circuit (Fig. Ib).

The steepness of the rise in the control voltage SPsAs function of the input voltage D generated by the resistance rr.ri'-ix! 9 can be set by a potentiometer.T'f-T 1.9a, the wiper of which is connected to the free charge of the output potentiometer 21 of the resistance matrix 19 FIG. 4 shows the course of the control voltage 5PaIs function of the input voltage D of the control signal transmitter 1 with two different settings of the potentiometer 19a.

The control signal generator 1 described above works as follows:

When the rotational speed of the plate cylinder changes, the output voltage of the tachometer generator 11 changes and thus the input voltage D of the control signal generator 1.This creates a voltage deviation at the input of the servo amplifier 15, which is amplified and activates the servomotor 17 14 and the SteL-.ig of the wiper 22 on the input potentiometer 18 of the resistance matrix 19 changed until the adjustment at the input of the servo amplifier 15 is restored and the servo motor 17 is thereby put out of operation. After the adjustment of the wiper 11 at the input potentiometer 18 of the resistance matrix 19, that at the output potentiometer 21 or at the output of the

^w Resistance matrix 19 applied between the wiper 22 and the conductor 23 control voltage SP changed according to the hyperbolic function set on the resistance matrix 19. The control voltage SP is fed to the input (+) of an AC amplifier 24 of the control circuit via a potentiometer 27 and the wiper 22, which an alternating current supply 25 is connected. The alternating current from the alternating current amplifier 24 is rectified by a diode bridge 26 and

for the purpose of stabilizing the alternating current amplification »24 Via the potentiometer 27, a resistor 28 and a capacitor 29 to the input (+) of the AC amplifier 24 returned.

The alternating current of the alternating current amplifier 24 is supplied to the drive motors 10 via primary windings 31a. 32a. 33a. 34a are supplied by control transformers, the secondary windings 31b, 32b, 33b, 34b of which are connected to diode bridges 37, 38, 39, 40, respectively. The resulting rectified voltages are each

Weil switched to potentiometer 41,42,43,44 that of Can be manually adjusted to the speed of each drive motor 10 individually to a special one To adapt the printing color or a special roll width. The wipers of the potentiometers 41,42,43,44 are located

to this, each «.-ili assigned to the four drive motors 10 Control units 45,46,47,48.

The output of the AC amplifier * <S is in In the illustrated embodiment, first on the primary winding 30a of a matching transformer.

F is transformed by this output to a specific voltage, which is measured at the secondary windings 30b, 30c, cf., ig, 3, in the conventional control circuit, a control switch 35 and a control relay 36 also are provided, which changes the control voltage SP and Operate the voltage of the AC output of the AC amplifier 24. The control relay 36 is energized when either “faster contacts” 35a or “slower contacts”

Contacts « 35b of the control switch 35 are closed, ie when the rotational speed of the plate cylinder increases or decreases. The control relay 36 opens a pair of normally closed contacts 36a and closes a pair of ^; normally open contacts 36Zj to change the tap from the secondary winding 30b of the input transformer. This changes the voltage on the primary windings 31a, 32a, 33a, 34a of the control transformers and, accordingly, the speed of the drive motors 10 , whereby the control relay 36 is de-energized and the contacts 36a closes and the Kontakie 36b opens. The secondary-side voltage of the input transformer can also be set manually by moving the tap on the secondary winding 30c. This manual adjustment is preferably attached to the main control panel of the printing machine and is therefore easily accessible.

For this purpose 2 sheets of drawings

Claims (5)

Patent claims: 1. Control circuit for the dampening unit of an offset rotary printing press with a first roller arrangement driven separately from the printing press, a second roller arrangement driven at the speed of the printing press and with a drive motor of controllable speed for the first roller arrangement for controlling the dampening solution supply ι ο a plate cylinder of the printing machine rotating at variable speed, the control circuit having a control signal transmitter for controlling the drive motor, characterized in that the control signal transmitter ΐί (1) is preceded on the input side by a signal transmitter through which the control signal transmitter (1) is linearly of the rotational speed of the plate cylinder dependent input voltage (D) can be applied, and that at the output of the control signal generator (1) a control / voltage (SP) for the drive motor (iö) of the first roller arrangement is applied, the value of which increases with increasing rotational speed windiness of the plate cylinder increases asymptotically after a hyperbolic function « 2. Control circuit according to claim 1, characterized in that the signal generator is a tachometer generator (II) which emits a DC voltage proportional to the rotational speed of the plate cylinder, and that the control signal generator (1) has a resistance matrix (19) whose input potentiometers (18) are linear according to the input voltage (D) agree wiper (22) and whose output potentiometer (21) has a conductor (23) and nit the input potentiometer (18) is connected by cross connectors (20) which are arranged so that the control voltage (SP) a between the wiper (22) of the input potentiometer (18) and the conductor (23) is the DC voltage that increases asymptotically according to a hyperbolic function with increasing input voltage (D). 3. Control circuit according to claim 2, characterized characterized in that the tachometer generator (11) is connected directly and via the wiper of a trimming potentiometer (14) to the inputs of a servover amplifier (15) and that to the output the servo amplifier (15) has a servomotor (17), mechanically with the wiper of the adjustment potentiometer (14) and with the wiper (22) of the Input potentiometer (18) of the resistor matrix (19) is coupled. 4. Control circuit according to claim 2 or 3, characterized in that the output potentiometer (21) of the resistor matrix (19) with the Connected to the wiper of a second output potentiometer (19aJ. Through which the steepness of the Increase in control voltage (S / ^ is adjustable. 5. Control circuit according to one of the preceding Anspiliehe, characterized in that the Control signal generator (1) is connected on the output side to a controlled AC amplifier (24) which is connected to the AC power supply (25) for the drive motor (10) is connected, and that the AC amplifier (24) is followed by a matching transformer pOa ^. The invention relates to a control circuit for the Dampening unit of an offset rotary printing press with a first roller arrangement driven separately from the printing press, and a second with the Speed of the printing machine driven roller arrangement and with a controllable speed drive motor for the first Roller arrangement for controlling the dampening solution supply at a variable speed rotating plate cylinder of the printing machine, the control circuit having a control signal generator for the Has control of the drive motor A known control circuit of this type (4823 Harris Form Roll Dampeners; Harris-Seybold Company, Cleveland, Ohio) is: intended for the drive motor of a fountain roller in a dampening unit together with a metering roller, a first roller arrangement forms the dampening liquid from a tub A second roller arrangement of the dampening system consists of a dampening roller, which on the one hand a plate cylinder and on the other hand against the fountain roller and at the speed of the Plate cylinder is driven. The dampening liquid transferred to the plate cylinder is absorbed by the The speed of rotation of the dip roller is determined. A manually operated control signal generator is also provided The form of a rotary switch is provided, which depends on the display of the on the plate cylinder transferred portion of the wet liquid can be adjusted. The control signal emanating from the control signal generator acts through the control circuit the drive motor of the immersion roller and thus causes the desired change in the rotational speed of the immersion roller and thus of the transferred Wet liquid content. Especially with offset rotary printing machines relatively thin pressure plates, it comes to an optimal setting and a constant and precise Control of the moist liquid supply, which changes with the speed of rotation of the Pli-tenzy linder target. Accordingly, the object of the invention is to provide a control circuit of the aforementioned type create, which enables the drive motor for the first roller assembly depending on the To control printing speed so that always an optimal print quality with regard to the dampening solution supply is obtained. This object is achieved according to the invention in that a signal generator is connected upstream of the control signal generator on the input side, through which the control signal generator can be acted upon by an input voltage that is linearly dependent on the rotational speed of the plate cylinder and that a control voltage for the drive motor of the The value of the first roller arrangement is applied asymptotically with increasing rotational speed of the plate cylinder according to a hyperbolic function increases. In the control circuit according to the invention, a control signal generator is thus provided whose control voltage is not occasionally dependent on the relative proportion of the wet wedge that is transferred to the plate cylinder, set by hand but a control signal generator whose control voltage is constantly and optimally adapted to the speed of rotation of the plate cylinder is adapted. The sub-claims relate to characteristics