DE3621093C1 - Double-sheet detection arrangement - Google Patents

Abstract

The double-sheet detection arrangement has a reading receiver 3 and, arranged on both sides thereof, light receivers 1, 2 for acquiring control-cycle signals. The signal of the reading receiver 3 passes via two parallel branches, each with a storage capacitor 17, 27, to the inputs of a comparator 32 whose output is applied to an actuator 33. In the first branch, a voltage-halving circuit 18, 19, 25 is provided. In a cycle-signal acquisition circuit 6 to 13, the light receiver 1 disposed upstream in the passage direction of the sheets effects the acquisition of a reset signal driving the voltage-halving circuit, the light receiver 2, disposed downstream, effects the acquisition of a reading-cycle signal driving the reading amplifier 15 and both together effect the acquisition of an interrogation-cycle signal driving the comparator 32. <IMAGE>

Description

The present invention relates to a double sheet Detection arrangement as used by counting machines for banknotes or in printing machines where prevented must be that two sheets from the stockpile at the same time be removed and run through the printing station with the As a result, only the top sheet is printed.

A special application is the printing of labels for pharmaceutical products with current data such as batches number or expiry date. If in such a press the labels peeled off a pile and after the Printing process can be put back on a stack, two labels on top of each other as double sheets tion, the not agile data is missing.

To avoid these faults, fork barrier devices are required known that work with fluoroscopy of the leaves, which is in the screening of a leaf and the Difference resulting from fluoroscopy detected becomes. Depending on the transparency of the sheets, the work must point of the luminous flux after crossing the current  Sheet sensing circuit can be set by hand which is difficult work. In case of strong light absorption the or reflective sheets, for example labels with an extensive colored or even black print precise setting and reliable operation of the Almost impossible to arrange.

From DE-OS 31 18 330 is a double sheet detection arrangement with a continuous leaf from one side illuminating light source and one passing light current reading receiver on the other side known this being followed by a sense amplifier, the Output signal via two parallel branches, in the first signal processing takes place to a comparator reaches, the output of which acts on an actuator or display element.

In this known training there is signal processing in the first branch from an analog-to-digital conversion, one Storage of the received digital value and one again subsequent digital-to-analog conversion. It is in the di gital memory stored a signal that is characteristic is for a minimal amount of light that passes through the Leaves from the light receiver must be detected in order to avoid any Interference signal, e.g. B. to stop the press. During operation, this is then for each sheet run measured amount of light compared with the stored value. However, the storage value must be set, which also can be done by a counter circuit, but then in this a certain number of printed sheets can be set  must lead to the desired amount of light.

The known design can therefore only current measurement values compare with given or fixed sizes, but is not suitable for slow changes in the measured values due to e.g. B. gradually thicker or thinner Scrolling or slow soiling of the optics follow and yet when a first occurs To reliably address double sheet feed.

The object of the present invention is to create a Double sheet detection arrangement, the setting a the transparency of the sheets to be checked makes visible working points unnecessary and one too reliable automatic detection operation at regarding their transparency allows different sheets.

The task set is due to the characteristic features of claim 1 solved. The system automatically adjusts to each given the greatest transparency of the scrolling sheets and reliably detects the occurrence of first-time Ab deviations due to the  Running through double sheets.

The invention is described below by the description Exercise of an embodiment based on the beige given drawings further explained. It shows

Fig. 1 shows schematically the spatial arrangement of the elements of the sheet feed station;

Fig. 2 shows the circuit diagram of the arrangement;

Fig. 3 shows the waveforms of the Signalgewinnungsschal device;

. Figure 4 shows the signals present at the comparator inputs waveforms during undisturbed operation;

Figure 5 shows the signal curves pending at the comparator inputs upon arrival of a double sheet.

Fig. 6 shows a signal constant control circuit.

In Fig. 1, a reading diode 3 is arranged with bilaterally arranged receiver diodes 1 and 2 , against which a radiation source 4 is located. Leaves B run through the gap between them in the direction of the arrow and are to be monitored for the appearance of double sheets, that is to say two sheets lying one above the other. The diodes 1, 2, 3 are, for example, silicon photodiodes and the radiation source 4 is an infrared light source.

The receiver diodes 1 and 2 are used to generate the clock signals, which in turn control the sequence of the test processes. The clock signals are generated in the signal acquisition circuit which can be seen in the upper part of FIG. 2. The receiver diodes 1, 2 act as switching diodes with on-off function, in such a way that a zero signal is generated when exposed to the full light of the radiation source 4 and a positive voltage is generated when shielded by a continuous sheet B. . How this is effected with the series resistors 7, 6 can be seen from the signal acquisition circuit.

The signal generated by the receiver diode 1 U ₁ is visible in FIG. 3: At the time t ₁ reaches the front edge of a continuous sheet, the receiver diode 1, whereby the signal of zero jumps to a positive value. At time t ₃ , the rear edge of the sheet runs in front of the receiver diode 1 , so that it is hit by full light again and its signal springs back to zero.

The signal generated by the downstream in the traveling direction of the sheets lying Windwärts receiver diode 2 U ₂ provides time-delayed accordingly: At time t _2, the sheet reaches the detection area of the diode, and leaves it at the time t. ₄

These signals tapped between the resistors 7, 6 and the receiver diodes 1, 2 are processed via transistors 8, 9 , which work in conjunction with resistors 10, 11 as low-impedance voltage followers, by which the transistors 12, 13 are controlled. Transistor 12 is an NPN transistor and transistor 13 is a PNP transistor. The npn transistor 12 receives its collector voltage from the transistor 9 and its base voltage from the transistor 8 . The pnp transistor 13 receives its emitter voltage from transistor 8 and its base voltage from transistor 9 .

With this interconnection, the signal lines correspondingly designated in FIG. 3 result on the output lines designated U ₃ , U ₄ and U ₅ . Here, in the manner to be described below, U _{3 is} a reset signal, U _{4 is} a read clock signal, which feeds a sense amplifier 15, and U _{5 is} a query clock signal, which feeds a comparator 32 .

The reading diode 3 is connected as an element to an operational amplifier 15 which acts as a reading amplifier, so that it supplies a voltage corresponding to the radiation current (luminous flux) and thus the transparency of the leaves B. This can be seen in the lower part of FIG. 2, which shows the signal evaluation circuit. The radiation source 4 is fed in this embodiment via a resistor 14 and thus provides a constant radiation that acts on the reading diode 3 through the gap running through leaves. The sense amplifier 15 has the function of a current-voltage converter.

The output signal of the sense amplifier 15 enters a first branch with a diode 16 and a storage capacitor 17 and a second branch with a diode 26 and a storage capacitor 27 . In these branches provided discharge resistors 20 and 29 are so large that the discharge speed of the capacitors 17, 27 is small compared to the chronological sequence of the sheets to be checked for their correct separation. A weak discharge should therefore only take place from sheet to sheet. The correct choice of the discharge speed depends, as will become apparent from the following, on how quickly the system should adjust to a different transparency of the new sheets when changing the sheets to be checked.

The first branch has, in parallel to the storage capacitor 17, a further discharge circuit comprising a capacitor 18 , a resistor 19 parallel to the latter and a transistor 25 connected in series with these two. The capacitance of the capacitor 18 is equal to the capacitance of the storage capacitor 17 . When the transistor 25 is turned on (conductive), the capacitor 18 takes on half the charge of the storage capacitor 17 , so that the potential at its positive coating drops to half.

The transistor 25 is driven by the signal U ₃ via a differentiator made of capacitor 23 and opponent 14 . The latter generates a short drive pulse _, indicated by U _{3 a} , from the leading edge of the signal U ₃ . This turns on the transistor 25 , so that the capacitor 18 is fourth acti. After a charge portion of the storage capacitor 17 has been taken over by the capacitor 18, the latter discharges again via the parallel resistor 19 .

The voltages of the capacitors 17, 27 lie as a control voltage at the bases of transistors 22, 28 , which are connected as voltage followers and impedance converters. The output signals, which are strictly proportional to the input signals, are applied to the emitter resistors 21 and 30/31 . The output signal U _{6 of} the first branch is at the input of a comparator 32 , while the output signal U _{7 of} the second branch is tapped between the resistors 30, 31 which represent a voltage divider and reaches the other input of the comparator 32 . The resistors 31/30 behave like 1: 3, so that the signal U ₇ is three quarters of the emitter voltage of the transistor 28 .

At the output of the comparator 32 there is a relay 33 which acts on a display device or an actuator which brings about a desired reaction.

The voltage U ₇ at the minus input of the comparator 32 is the reference voltage. If the signal U ₆ at the plus input is above this reference voltage, the output of the comparator 32 carries current and the relay 33 remains energized; If the signal falls below U ₆ the reference voltage, the output of 32 is de-energized and the relay drops out.

The effect of the arrangement described results from the consideration of FIGS. 4 and 5. The observation is to be started between two test cycles, the previous test cycle having proceeded without a fault (without the occurrence of a double sheet). In this situation, neither the sense amplifier 15 nor the comparator 32 is supplied, and slowly falling voltages of approximately the same magnitude are present at the bases of the transistors 22 and 28 . Because of the voltage division by resistors 30, 31 , the reference signal U ₇ is approximately three quarters of the value of signal U ₆ .

If at the timet ₁ the front edge of the next LeafB in the area of the receiver diode1 arrives, generates the reset signalU _3rd with its front edge the control pulseU _{3 a} that the transistor25th  switches through. Thereby the tension takes over beer capacitor18th half the charge of the Storage capacitor17th. The tension at the base of the transistor22 and with it the tensionU ₆  falls to half of the previous value, namely to the levelU _8th and thus under tensionU ₇. So the arrangement is back set and prepared for the next exam.

At time t ₂ , the front edge of sheet B reaches receiver diode 2 , which triggers read clock signal U ₄ , which feeds sense amplifier 15 . Since the sheet is now in front of the reading diode 3, a signal corresponding to the transparency of the sheet appears at the output of the sense amplifier 15 . This charges the capacitors 17, 27 to the same voltage level and keeps them at this level during the reading cycle lasting up to t ₃ . When a single sheet passes through, the signal U ₆ , as shown in FIG. 4, assumes a maximum value and the signal U ₇ reaches a level of three quarters of the value of U ₆ .

At time t ₃ , the rear edge of sheet B reaches the area detected by receiver diode 1 , reading clock signal U ₄ falling to zero and interrogation signal U ₅ feeding comparator 32 occurring until time t ₄ . During this query, the signal U _{6 is} reliably above the signal U ₇ , which is the confirmation that only a simple sheet has gone through properly. The relay 33 remains energized and no action is triggered.

From time t ₃ on, both levels U ₆ and U ₇ slowly decrease due to lack of refilling by the sense amplifier 15 and the cycle repeats itself.

In Fig. 5 of the sequence is shown, if a double sheet enters the test station. The initial situation is the same as in FIG. 4 until time t ₂ , at which the sense amplifier is supplied with signal U ₄ .

Since the reading diode 3 is now acted upon by only about half the luminous flux, the signal at the output of the sense amplifier 15 will also remain correspondingly lower, namely below the value at which the capacitor 27 is still located anyway. The signal U ₇ will therefore not change at all at time t ₂ , but will continue to decrease slowly, and the signal U ₆ will rise somewhat, but will remain below the signal U ₇ .

During the subsequent polling cycle at time t ₃ , the situation at the inputs of the comparator 32 will therefore be reversed, so that the relay 33 drops out and causes a display which indicates the malfunction occurring in the sheet flow or triggers a measure for its elimination.

In order to compensate for the different transparency of the sheets and thus the diversity of the light currents acting on the receiver diodes 1, 2 and the reading diode 3 , the supply of the radiation source 4 can be regulated accordingly. According to FIG. 6, the radiation source 4 is supplied via a pnp transistor 34 , which is driven by the output of the second branch, namely the emitter voltage of the transistor 28 . In this way, increasing signal levels result in a falling supply to the radiation source 4 and there is constant regulation of the signal amplitudes with differing transparency of the sheets to be checked.

Claims (7)

1. Double-sheet detection arrangement with a light source ( 4 ) illuminating through running leaves and a light detector ( 3 ) which detects the passage of luminous flux on the other side with a downstream sense amplifier ( 15 ) whose output signal via two parallel branches, in whose he stem signal processing takes place to a comparator ( 32 ), the output of which acts on an actuator or display element ( 33 ), characterized in that a storage capacitor ( 17, 27 ) in each of the two branches and in the first branch for signal processing A controllable voltage halving circuit ( 18, 19, 25 ) is provided, and a photodiode ( 1, 2 ) is arranged on each side of the reading diode ( 3 ), the photodiode ( 1 ) of which is located upstream in the direction of travel of the sheets ( 1 ) for obtaining a voltage halving circuit ( 18, 19, 25 ) triggering reset signal (U _{3 a} ) and its downstream ( 2 ) to obtain a Begi nn of the signal defining the reading interval. 2. double sheet detection arrangement according to claim 1, characterized by a constantly effective voltage voltage divider circuit ( 30, 31 ) in the second branch. 3. Double sheet detection arrangement according to claim 2, characterized in that the voltage divider circuit ( 30, 31 ) in the second branch reduces the voltage value of this branch to three quarters. 4. Double sheet detection arrangement according to claims 1 to 3, characterized in that the voltage bisection circuit in the first branch has a capacitor capacitor ( 17 ) of this branch parallel capacitor ( 18 ) of the same capacity. 5. double sheet detection arrangement according to claim 4, characterized in that the parallel connection of the voltage bisection capacitor ( 18 ) by means of a transistor ( 25 ), which is driven by the reset signal (U _{3 a} ). 6. Double sheet detection arrangement according to one or more of claims 1 to 5, characterized in that for obtaining the reset signal (U _{3 a} ) and the beginning of the reading interval defining signal a circuit with two of the two sides of the reading diode ( 3 ) arranged photodiodes ( 1, 2 ) controlled transistors ( 12, 13 ), the first ( 12 ) is an npn transistor, the collector voltage of the first photodiode ( 1 ) and the base voltage of the second photodiode ( 2 ) is controlled and the emitter output signal Feeding the sense amplifier ( 15 ) controls, and the second ( 13 ) is a pnp transistor, the emitter voltage of which is controlled by the second photodiode ( 2 ) and the base voltage of which is controlled by the first photodiode ( 1 ) and the collector output signal of which supplies the comparator ( 32 ) controls. 7. Double-sheet detection arrangement according to one or more of the preceding claims, characterized by a constant control circuit for the amplitudes of the output signals of the reading amplifier ( 15 ), which includes a transistor ( 34 ) connected to the supply circuit of the light source ( 4 ), whose emitter-collector path lies in the supply circuit of the light source ( 4 ) and whose base is driven by the voltage level of the storage capacitor ( 27 ) of the other branch.