DE2309675A1 - PROCEDURE AND EQUIPMENT TO AVOID MISTAKE MEASUREMENTS ON THE BOW SYSTEM - Google Patents

Description

Procedure and equipment to avoid failure of the Arch system The invention relates to a method and a device for avoidance of incorrect measurements on the sheet system of sheet processing machines.

We know the reflection measuring principle and the light barrier principle. With the reflection measuring principle, the out of all the measuring devices cannot be negative effect, because if the encoder fails, the value signal has the same value as at Pehlbogen.

With the light barrier principle, however, a failure of the encoder is deceptive a good sheet, as in both cases no light signal hits the receiver. The printing press will continue to run in normal operation in both cases. So can If the encoder fails, an uncontrolled run-in of an incorrectly come close to the bow. This allows you to know the cause of malfunctions in the printing press will. The invention relates to the light barrier principle.

It is known to control the position of the sheet edges at the feed marks of sheet processing machines above the sheet a photoelectric one To arrange encoder swiveling and below the sheet a photoelectric To arrange recipients (BRD-PS 835 749).

The disadvantage here is that with this arrangement the measured values do not allow a clear statement. If the photoelectric transmitter fails, in the evaluation circuit the same signal as in the presence of an ordnungsgosäß adjacent bow, which prevents the light from entering the receiver.

The purpose of the invention is to prevent failure of the measuring device for checking the position of the printing press due to the infeed of incorrectly fitting Sheet malfunctions or damage to the printing machine.

The invention is based on the object of developing a method that a separate evaluation of the states "good sheet" and "encoder failure" is guaranteed and to develop a device that, in contrast to the "good sheet" state for the state "encoder failure" sees switching elements sw preventing sheet entry.

According to the invention, the object is procedurally achieved by that in addition to a faulty sheet check and its evaluation at a given cycle time, after the sheet has been drawn over the cover marks after proper acceptance, the cover marks are swiveled in and before covering the measuring points by the next sheet, i.e. immediately before arriving at the feed marks, it is checked whether the measuring points are functional and, in the event of a defect in the measuring points, the system locked as well as a signal lamp is made to light up.

According to the invention, the object is achieved in terms of equipment in that that a common one by measuring points for the detection of oblique bow or Pehlbogen during a first packet signal and its evaluation formed first evaluation circuit for the system lock with a signal supplied by the measuring points receiving ODBR element, comparing this signal with a second clock signal Pulse gates and switching elements formed the functionality of the measuring points with a first sheet above the cover mark and a subsequent sheet Check and display the sheet in front of the measuring points and with the cover mark swiveled in connected to trigger a system blocking pulse serving second evaluation circuit is.

The invention is to be described in more detail below using an exemplary embodiment are explained0 In the accompanying drawing Fig. 1: Circuit arrangement Fig. 2: Representation of the arc position In Fig. 1 is the circuit evaluation of the measurement results are shown.

The first measuring point 1 is via a first Schmitt trigger 2 and a first amplifier 3 is connected to the first evaluation circuit 4.

The second measuring point 5 is via a second Schmitt trigger 6 and a second amplifier 7 also connected to the first level circuit 4, The output of the first amplifier 3 is once negated with a first via a Input 8 provided first pulse gate 9 with an A input 10 of a first bistable Flip-flop 11 and on the other hand a first inverter 12 and one with a second negated input 13 provided second pulse gate 14 with a B input 15 of the first bistable flip-flop 11 connected.

The output of the second amplifier 7 is once over one with one Third pulse gate 17 provided with third negated input 16 and having a C input 18 of the second bistable multivibrator and on the other hand about a second one egator 20 and a fourth pulse gate provided with a fourth negated input 21 22 is connected to a D input 23 of the second bistable multivibrator 19.

The æ-huegang 24 of the first bistable trigger stage 11 and the F output 25 of the second bistable flip-flop 19 are led to a triple AND element 26, The output of the triple UD element 26 is via a third amplifier 27 with the system locking relay 28 connected.

The outputs of the first amplifier 3 and the second amplifier 7 are connected to the second evaluation circuit 29 on the OR gate, its output via a third inverter 31 and via a fifth pulse gate 32 is connected to a G input 33 of a third bistable multivibrator 34.

The H output 35 of the third bistable multivibrator 34 is open once the triple AND gate 26 out and on the other hand via a fourth amplifier 36 connected to the fault indicator relay 37.

The first pulse gate 9 also has a first clock input 38, the second pulse gate 14 also has a second clock input 39, the third Pulse gate 17 continues to have a third clock input 40 and the fourth pulse gate 22 a fourth clock input 41. The first, second, third and fourth clock input 38, 39, 40, 41 are connected to one another and to a first clock input 42. The fifth pulse gate 32 has a fifth clock input 43, which is connected to a second Clock input 44 is connected.

The first bistable multivibrator 11 also has a first one Zero connection 45, the second bistable multivibrator 19 continues to have a second Sulletellungsanschluss 46 and the third bistable multivibrator 34 also have a third zero position connection 47. The first, second and third zero position connections 45, 46, 47 are one below the other and connected to a zero position input 48.

In the initial state, there is no sheet at the positioning marks 53.

The measuring points 1,5 transmit an O signal. At the outputs of the first amplifier 3 and the second amplifier 7 seeks an 0 signal.

To explain the first evaluation circuit 4 it must be said that can only cause signal changes to trigger a switching process. So lies now a bow properly at the positioning marks 53 is produced at the exit of the measuring points 1.5 an L signal. There is an L signal at the outputs of the amplifiers 3, 6. These The signal changes from 0 to L via the first pulse gate 9 or via the third Impulse gate 17 causes a signal change from L to 0 by negation at the time of measurement, which acts on the A input 10 or input 18 when a cycle 1 is applied. Through this arises at the E output 24 of the first bistable trigger stage 11 or at the F output 25 the second bistable multivibrator 19 a signal.

Both signals are at the triple AND gate 26. The remaining input of the triple AND element 26 carries an L signal as long as the measuring points 1, 5 are functional.

The system blocking relay 28 receives a signal via the third amplifier 27 and sees that the circuit for the system blocking magnet 54 is interrupted with the aid of the closing contact 55.

When the normal arc run is interrupted by a crooked or missing arc if a signal occurs at the first measuring point and / or at the second measuring point 5, at the first amplifier 3 and / or at the second amplifier 7 an 0 signal.

The signal change from L to 0 is caused by double negation am first inverter 12 and on the second pulse gate 14 and / or on the second inverter 20 and a signal change from L to 0 at the fourth pulse gate 22 at the time of measurement, which acts on the B input 15 or the D input 23 when cycle 2 is at the second cycle input 39 and applied to the fourth clock input 41.

This results from the tilting of the first bistable trigger stage 11 or the second bistable multivibrator 19 at the E output 24 or at the F output 25 a signal. As soon as from the E output 24 or from the f output 25 or from the H output 35 when an O signal reaches the triple UmD element, the system locking relay 28 drops from, the closing contact 55 closes and the system blocking magnet 54 attracts.

In the initial state there is no sheet at the positioning marks 53. The measuring points pass on an O signal. At the outputs of the first amplifier 3 and the second Amplifier 7 and at the inputs of the OR gate 30 is a signal. By Negation at the third negator 31 is achieved at the input of the fifth pulse gate 32 a signal is present. However, this L signal does not reach the third bistable Tilt step 34.

If the system is properly positioned at the positioning marks 53, the exit is located the first measuring point 1 and at the output of the second measuring point 5 a signal. At the output of the first amplifier 3 and the second amplifier 7 is present L signal on, via dth OR gate 30 and after negation in the third inverter 31 cs as a signal to the input of the fifth pulse gate 32.

However, this signal cannot go to the third bistable flip-flop stage 34 arrive, since there is no clock signal at the fifth clock input 43.

At the point in time when the cover mark 51 is under the in the printing machine running first sheet 5u again in the starting position over the first measuring point 1 and the second measuring point 5 and the following sheet 52 is the measuring point 1 and has not yet reached measuring point 5 (FIG. 2), fact 2 is entered via the second clock input 44 given to the fifth clock input 43.

At this point in time, the first measuring point leads 1 and the second measuring point 5 but again a signal, so there is the second AND condition at the fifth pulse gate again is not fulfilled.

In the following, the cover mark 51 is over the first measuring point 1 and of the second measuring point 5. The beam path is through the following arc 52 not interrupted yet. The inputs of the triple AND gate 2b ruiir an L signal. The output of the first amplifier 3 and the second amplifier 7 carry signals as long as the first measuring point 1 and the second measuring point 5 are functional. There is an L signal at the input of the fifth pulse gate 32.

If the first measuring point 1 and / or the second measuring point 5 is defective, eo is at the output of the first amplifier 3 and / or at the output of the second Amplifier 7 has an L signal, whereby a 32 at the input of the fifth pulse gate O signal is present. At this point in time where the cover mark 51 is pivoted in and the following sheet 52, the first measuring point 1 and the second measuring point 5 still not has reached, brings clock 2 via the second clock input 44 a clock 2 and the third bistable flip-flop 34 toggles so that the H output emits a signal. In order to the triple element 26 is blocked, the system blocking relay 28 drops out.

The make contact 55 closes and the hnlagesperrmagnet 54 pulls at. At the same time, the defect indicator relay 37 is actuated.

Clock 1 is given to the first clock input 42 at the point in time, to which a sheet should properly rest on the winleg mark. Measure 2 becomes given the point in time on the second file input 44 at which the first sheet 50 is already drawn over the cover mark 51, the cover mark 51 is swiveled in, but the following sheet 52 does not yet have the first measuring point 1 and the second measuring point 5 has reached.

The zero setting input 48 is used to reset the first bistable Flip-flop 11 via the first zero position connection 45, the second bistable flip-flop 19 via the second Iiullstellungsanschluss 46 and the third bistable multivibrator 34 via the third zero position connection 47.

The third amplifier 27 and the fourth amplifier 36 are used for power amplification of the measured and processed variables to ensure that the system locking relay responds 28 or the defect indicator relay 37.

Claims (2)

Claims: (1.) Method for reporting incorrect measurements according to photoelectric measuring points working on the sheet feeder using the light barrier principle sheet processing and sheet processing machines, characterized in that in addition to one Missing sheet control and its evaluation at a given cycle time after the sheet was drawn over the cover marks after proper acceptance Cover marks are swiveled in and before the measuring points are covered by the next one Sheet, so immediately before arriving at the landing marks, it is checked whether the Measuring points are functional and, in the event of a defect in the measuring points, the system locked as well as a signal lamp is made to light up. 2. Device for performing the method according to claim t, characterized characterized in that a usual by measuring points (1; 5) for the constitution of skew bow or missing bow formed during a first cycle and its evaluation first evaluation circuit (4) for the system lock with one by one of the Measuring points supplied signal receiving OR gate (30), this signal with a second clock signal comparing pulse gate (32) and switching elements (49) formed, the functionality of the IJeßellen (1; 5) in the location of a first Sheet (50) above the cover mark (51) of a following sheet (52) before the measuring points (1; 5) and when the cover mark (51) is swiveled in, checking and indicating for triggering a system blocking pulse serving, second evaluation circuit (29) is connected. L e r s e i t e