EP0242622A1 - Monitoring device for the supply of overlapping sheets to a printing press - Google Patents

Abstract

In a monitoring device for the shingled sheet feed to printing machines, with a scanning roller (13) rotatably mounted on a support above a base of the shingled sheets, the support being adjustable by a servomotor in such a way that the scanning roller is only rotated when a specific one Number of sheets lying one above the other, with a sensor (14) which interacts with the scanning roller (13), and an intermediate roller which can be moved at right angles to the plane of the sheets transversely to their axial direction can be provided between the scanning roller and the support, so that the scanning roller (13) is rotatably supported indefinitely, that the sensor (14) is designed such that it detects every rotational movement of the scanning roller (13), that a device for measuring the distance of the scanning roller (13) or the intermediate roller from the base of the scaled Arch is provided that a control device is provided which is connected to the sensor, the meas device and the servomotor is coupled, that a device is provided for generating a signal which is characteristic of the angle of rotation of the printing press and which is fed to the control device, and that the control device is designed such that it monitors the scale structure. This makes handling easier.

Description

The invention relates to a monitoring device for the shingled sheet feed to printing machines, with a scanning roller rotatably mounted on a support above a base of the shingled sheets, the support being adjustable by a servomotor such that the scanning roller is only rotated when a certain number of bow lie one above the other, with a sensor interacting with the scanning roller, wherein an intermediate roller that can be moved perpendicular to the plane of the sheet transversely to its axial direction can be provided between the scanning roller and the base.

In such a device known from DE-PS 31 18 010, the scanning roller, which does not come into direct contact with the sheet but is driven by a roller arranged between the sheet and the scanning roller, can be rotated to a limited extent. A sensor detects when the scanning roller has traveled a predetermined angle of rotation and then emits a signal. A spring is provided which pivots the scanning roller back into a basic position from the last-mentioned position. In the basic position, a contact is actuated by the scanning roller and thereby a control lamp is kept in the extinguished state. The scanning roller and the intermediate roller are mounted on a carrier. The height of the carrier and thus the height of the intermediate roller above the base of the sheet, a driven roller, can be adjusted by an electric motor to be switched by an operator. The setting is made so that, for example, the intermediate roller does not touch the scanning roller in the case of two sheets lying one above the other, whereby this remains in the basic position, but in the case of three sheets the intermediate roller rotates the scanning roller against the force of the spring. The indicator lamp lights up. At the end of the triple overlap, the indicator lamp goes out again. This enables the operator to check the correct setting of the monitoring device and, if necessary, to bring about a correct setting by switching on the electric motor. If the overlap is too long, there is a Multiple sheets before, so the sensor responds and causes an error signal.

In the known device, the length of the overlap region, in which the sensor has not yet triggered, is predetermined by the size of the pivoting angle of the scanning roller until the sensor is triggered and cannot be changed or can only be changed with difficulty. Especially when using sheets with a thickness that is not used for the first time, adjusting the monitoring device requires increased attention. Although it is provided for setting up the known machine, the motor which adjusts the height of the carrier is then subjected to a drive pulse which increases the distance of the scanning roller from the base of the paper when the scanning roller rotates, it being assumed that the motor should only be switched on , if the number of overlapping sheets leading to twisting is smaller than intended. However, this process must be monitored by the operator.

After a permissible overlap has occurred, the scanning roller of the known machine requires a certain time to return to its basic position. So that the scanning roller can follow short distances between the overlaps, a strong restoring force must be generated for the scanning roller and, accordingly, a sufficiently strongly pre-tensioned spring must be provided. Tensioning this spring during an overlap brakes the sheets and can affect sheet transport and damage the surface of the sheets, especially if they are already printed.

The invention has for its object to provide a monitoring device of the type described that is easy to handle. This object is achieved according to the invention in that the scanning roller is rotatably supported indefinitely, that the sensor is designed such that it detects every rotational movement of the scanning roller that a device for measuring the distance of the scanning roller or the intermediate roller from the base of the scaled Sheet is provided, that a control device is provided, which is coupled to the sensor, the measuring device and the servomotor, that a device is provided for generating a signal characteristic of the angle of rotation of the printing press, which is fed to the control device, and that the control device in such a way is trained to monitor the build-up of the shed.

Such monitoring is possible because the signal characteristic of the angle of rotation can be used to determine whether the leading edge of a sheet actually arrives at the point in time at which it must arrive at the scanning roller, or whether the leading edge of a sheet is absent at that point in time or arrives at other times. The device for measuring the distance of the scanning roller from the support enables the thickness of the sheet running under the scanning roller to be determined quickly, and this information can be used for further monitoring of the scale build-up.

The signal which is characteristic of the angle of rotation of the machine is expediently a clock signal which indicates the respective angle of rotation of the printing machine with sufficient accuracy, for example for a full revolution of the printing machine 1024 pulses. The rotary movement of the scanning roller is not or not necessarily used to detect the length of an overlap area of several sheets.

It is known from DE-OS 29 30 270 a control device for the supply of sheets, with which irregularities in the sheet feed are to be detected, in which device a displacement sensor is provided, by means of which the distance between two rolls, the thickness of a between sheets lying between the rolls, can be measured. In the known device, however, the roller coupled to the displacement sensor is always pressed against the other roller by a spring, as a result of which particularly sensitive sheets can be impaired in their surface quality. The role coupled to the position encoder is not used to determine the length of the overlap area.

The invention comprises two closely related embodiments, wherein in one embodiment the scanning roller interacts directly with the sheets, and in the other embodiment, as in the aforementioned prior art, the scanning roller is rotated by an intermediate roller when the intermediate roller passes through sheets passing beneath it is raised and rotated.

Another advantage of the device according to the invention without an intermediate roller is that the device can be adjusted so that the scanning roller is not in contact with the sheet during trouble-free sheet transport. Only when there are too many sheets lying on top of each other does the scanning roller come into contact with the top sheet, is rotated by it, and the sensor reports this and emits an error signal.

The distance between the leading edges of immediately consecutive sheets depends on the type of feeder. Therefore, the maximum number of overlapping sheets depends on the sheet length. In simple embodiments of the invention, the number of the maximum overlapping sheets can be entered into the control device by the operator, or the sheet length can be entered, and the device determines the number of the maximum overlapping sheets.

In one embodiment of the invention, however, it is provided that the control device is designed such that it automatically determines the arc length. This is done by detecting a decrease in the total thickness of the sheets lying one above the other and thereby determining the rear edge of a sheet. This embodiment makes it possible for the device to determine the number of sheets which are permissibly overlapping each other completely automatically.

If the number of the maximum overlapping sheets is known, there is the advantageous possibility that the adjustment of the scanning roller or intermediate roller to such a height that the sheet only the role that comes into direct contact with them, namely the scanning roller or intermediate roller touch where a predetermined number of sheets overlap, can be made automatically and quickly. Advantageously, the setting is such that the height of the scanning roller or intermediate roller, ie the smallest distance of the scanning roller or intermediate roller from the base, which is generally will be a driven roller that is less than one sheet thickness greater than the total thickness of the sheets that are permissibly overlapping.

In one embodiment of the invention, the control device is designed such that when the first sheet passes under the scanning roller or intermediate roller, it determines the thickness of the sheet by adjusting the height of the support and adjusts the scanning roller or intermediate roller to a height which is greater than the thickness of a single sheet, but less than twice the sheet thickness.

If the leading edge of a second sheet which overlaps with the first sheet is then recognized, the control device causes the scanning roller or intermediate roller to be set to a height which is greater than twice the sheet thickness but less than three times the sheet thickness, and so on away.

In one embodiment of the invention, the control device is designed in such a way that, while the sensor signal indicating the rotation of the scanning roller is present, it evaluates the signal which is characteristic of the angle of rotation of the printing press, in order thereby to determine the length of the overlap region.

In one embodiment of the invention, a force generating device is provided which loads the scanning roller with a force which can be set by the control device. While in the prior art, for example in the last-mentioned document, the force with which the scanning roller rests on the top of the sheet by a Spring is specified and can only be adjusted by hand, the described embodiment thus enables the force to be set automatically. The sheet thickness can serve as a measure for this, possibly together with an indication of the paper type. The force to be set can be specified in a memory of the control device. As far as the paper thickness determines the force, the control device, which automatically detects the paper thickness, can automatically set the force itself. The force can be adjusted largely independently of the position of the scanning roller if necessary. According to one embodiment of the invention, an electric motor is provided as the force generating device.

In one embodiment of the invention it is provided that the control device compares the signal supplied by the sensor and the signal which is characteristic of the angle of rotation of the machine and emits a fault signal in the event of deviations which exceed a predetermined amount. While the invention described at the outset does not require precise detection of the angle of rotation of the scanning roller because only the fact of a rotary movement of the scanning roller has to be ascertained, it is provided in accordance with this embodiment that the scanning roller emits a signal which is characteristic of the angle of rotation of the scanning roller and which provides conclusions to the length of the overlap area. This signal is compared with the signal which is characteristic of the angle of rotation of the machine, which is preferably a clock signal and whose clock frequency is a measure of the transport speed of the sheets. For example, if there are inadmissible deviations between the rotation angle of the scanning roller (or the time during which the scanning roller rotates) and the signal dependent on the machine cycle, as a result of a blocking of the scanning roller, this is recognized.

In one embodiment of the invention, the signal which is characteristic of the angle of rotation of the machine is a clock signal, and the control device is designed in such a way that it compares the occurrence of the leading edge of a sheet on the scanning roller or intermediate roller with the phase of the clock signal and an inadmissible deviation Emits a fault signal. This further development of the invention makes it particularly easy to monitor whether the leading edges of the sheets always occur within a certain time interval, which is determined by the machine cycle, as is the case when the device feeding the sheets to the printing machine works properly.

• Fig. 1 schematisch und teilweise abgebrochen eine Druck­maschine mit einem Bogenanleger,
• Fig. 2 den im Bogenanleger der Fig. 1 vorgesehenen Teil der Überwachungsvorrichtung in einer schemati­schen Darstellung,
• Fig. 3 eine andere Ausführungsform der in Fig. 2 gezeig­ten Vorrichtung,
• Fig. 4 ein Blockschaltbild der Überwachungsvorrichtung,
• Fig. 5 eine Darstellung verschiedener Signalverläufe,
• Fig. 6 eine Darstellung, in der zwei verschiedene Be­triebsmöglichkeiten der Vorrichtung gezeigt sind.

Further features and advantages of the invention result from the following description of exemplary embodiments of the invention with reference to the drawing, which shows details essential to the invention, and from the claims. The individual features can be implemented individually or in any combination in any combination in one embodiment of the invention. Show it

• 1 schematically and partially broken off a printing press with a sheet feeder,
• 2 shows the part of the monitoring device provided in the sheet feeder of FIG. 1 in a schematic illustration,
• 3 shows another embodiment of the device shown in FIG. 2,
• 4 is a block diagram of the monitoring device,
• 5 shows a representation of different signal profiles,
• Fig. 6 is an illustration in which two different operating options of the device are shown.

In Fig. 1 a part of a printing press 1 is shown schematically, which are fed from a stack 3 by a sheet feeder 2 overlapping sheets of paper. The partially overlapping sheets pass through a scanning device 4 and reach the printing press 1 via a feed table 5. A clock generator 6 is connected to a gearwheel of the printing press 1, which rotates one full rotation with each press that corresponds to a single printing process. This is only shown schematically and has a reticle with 1024 marks in the example. The rotation of the reticle is sensed by a light barrier that generates a clock signal corresponding to the rotation of the reticle. The instantaneous angle of rotation of the printing press 1 can be determined from the clock signal. A guide rail 8 (FIG. 2) arranged above the feed table 5 ensures that the paper sheets cannot get too far up.

The scanning device 4 is shown in FIG. 2 in a side view. A rotatingly driven transport roller 9 projects into a recess in the feed table 5 and in FIG. 2 conveys paper sheets coming from the right to the left. A multi-armed lever 11 is pivotally mounted on a shaft 12 on a machine-fixed part 10. The end of the lever 11 pointing to the left in FIG. 2 carries a scanning roller 13 which can be scanned by a sensor 14 attached to the lever 11 Line marking 15 carries, which forms an increment encoder together with the sensor. The sensor 14 is able to detect a rotation of the scanning roller 13. In one embodiment of the invention, the sensor 14, together with further devices, is also able to determine the angle of rotation of the scanning roller 13.

On a protruding projection 17 of the machine-fixed part 10, a rod 18 is articulated, which carries a thread. On this thread, a sleeve 26 is screwed, which merges into a widening 27, which forms a stop for the movement of another arm 28 of the lever 11 to the left in FIG. 2. The sleeve 26 is connected to the shaft of a motor 22 designed as a DC motor. The current is supplied via lines 23. A potentiometer 20 is fastened to the housing 24 of the motor on the left-hand side of the motor 22 in FIG. 2. The shaft of the motor 22 is connected to the wiper of the potentiometer 20, and the connecting line of the potentiometer 20 connected to the wiper is provided with the reference number 21. The housing 24 of the motor is secured against rotation in a manner not shown by a projection of the housing which engages in a slot in a machine-fixed part. The motor 22 can therefore rotate the sleeve 26, whereby the total length of the rod 18 and sleeve 26 is increased or decreased depending on the direction of rotation of the motor 22, so that the distance of the stop from the projection 17 can be changed.

By turning the sleeve 26, the clear distance 30 between the transport roller 9 and the scanning roller 13 can be changed if it is not raised by sheets.

The shaft 12, to which the lever 11 is attached, is connected to the rotor of a further DC motor 32, the field of which is generated by permanent magnets. An armature winding 33 of the further motor 32 can be supplied with direct current, which depending on the direction of the current exerts a torque on the lever 11 in the view in FIG. 2 in the counterclockwise or clockwise direction. As a result, depending on the direction of the current and the current intensity, the pressure exerted by the scanning roller 13 on the sheet located between it and the transport roller 9, which is generated by the weight of the individual parts taking into account the lever ratios, can be increased or decreased in order to thereby achieve a desired pressure or generate a desired force generated by the sensing roller 13.

The embodiment of a scanning device shown in FIG. 3 differs from the example shown in FIG. 2 essentially in that the scanning roller 13 cannot come into direct contact with the top of the paper sheets, but in that one between the scanning roller 13 and the transport roller 9 Intermediate roller 40 is arranged, the weight of which is borne by a tension spring 42 which is anchored to the lever carrying the scanning roller 13. In this exemplary embodiment, the scanning roller 13 is only rotated when the intermediate roller 40 has been moved so far away from the transport roller 9 by paper sheets that it touches the scanning roller 13. In this device, the lowest possible position of the scanning roller 13 and thus (taking into account the properties of the tension spring 42) of the intermediate roller 40 can be predetermined by the adjustment of the sleeve 26, and by the current supplied to the further motor 32, as long as the lowermost one just mentioned Position is not reached, the force can be set with which the intermediate roller 40 presses on the paper sheet.

FIG. 4 shows the block diagram of a monitoring device according to the invention, which contains the device according to FIG. 2. A microcomputer 51, for example an Intel SBC86 / 12, is connected via a bus system 70 to a machine control device 50, by means of which the printing press 1 can be controlled. The connection described enables data exchange between the machine control 50 and the device for monitoring the sheet feed.

The clock generator 6 (cf. FIG. 1) on the printing press 1 supplies a machine clock signal to the microcomputer 51 on a line 78, which can calculate path lengths in connection with a signal appearing on an output line 71 of the sensor 14 and process them further. The required pressing force, which is generated by the further motor 32, is calculated by the microcomputer 51 on the basis of the thickness of the individual paper sheets determined by means of the potentiometer 20 and is passed on to a digital / analog converter 59 in the form of a digital setpoint on a line 75. A motor current control 60 generates a motor current proportional to an analog setpoint value 76 appearing at its output and supplies it to the further motor 32. The motor current is kept constant by means of a negative feedback. The analog value proportional to the distance 30 (FIG. 2), which is supplied by the potentiometer 20 via its line 21 connected to the slider, is first fed to an analog / digital converter 54, the output signal of which is fed to the microcomputer 51 via a line 72. The distance 30 is set by the motor 22, to which the required current is supplied via a driver stage 56. The driver stage 56 can be controlled both manually via a button 57 and also automatically via an output signal of the microcomputer 51 supplied on a line 73.

A display 58, which works with light-emitting diodes and is controlled by the microcomputer 51, shows the operator the correct sheet overlap and any missing or multiple sheets that may occur.

The operating mode of the monitoring device can be set via a symbolically represented switch 53 which can be operated manually.

5, the occurrence of some signals of the monitoring device is explained. Reference number 80 schematically shows the overlap of individual paper sheets B, the front end region of a following sheet in the direction of movement being below the rear end region of the preceding sheet. The representation 80 shows only simple overlaps. The curve 81 shows the total thickness of the sheets B, as it occurs over time at the scanning roller 13, with dashed lines. The total thickness varies between the thickness d of a single sheet and twice the thickness of a single sheet, namely 2d, where two sheets B overlap. The height of the scanning roller 13 above the transport roller 9 (FIG. 2) is larger by a certain percentage Td (less than 100%) than the thickness d of a simple sheet in order to suppress disturbances, for example as a result of slight variations in the thickness of the sheets than twice the sheet thickness 2d. This fact is illustrated by a scanning roller 13 shown above curve 81.

At the times when there are overlaps between two sheets B on the scanning roller 13, the scanning roller 13 rotates, and the sensor 14 thus provides one by the angle of rotation of the Sampling roller 13 has a signal which is determined in terms of its duration and is represented by curve shape 82. The size S1, which corresponds to the duration of the output of this signal, corresponds to the length of an overlap of two sheets B in the example. During a subsequent path S3 of the movement of the sheets B, the sensor 14 does not supply any signals because the scanning roller 13 does not touch any sheets and therefore stands still. The distance S2 is constant due to the construction of the sheet feeder. This distance S2 corresponds to the distance between the front edges of two immediately consecutive sheets and is the sum of the sizes S1 and S3. This relationship only applies if, as in the example, a maximum of two sheets overlap. The quantities S1, S2 and S3 are not determined by counting the pulses of the signal supplied by the sensor 14, but rather by counting the pulses of the signal supplied by the clock generator 6, which is constantly present when the printing press is running. The sheet length b, which can be used for setting format-dependent devices of the printing press 1, is determined by the microcomputers 51 from the sizes S1, S2 and S3 and from the number of sheets overlapping each other. In the example, where only two sheets can overlap with a correct scale structure, size b is the sum of S1 and S2.

The determination of the length of the named variables on the basis of the number of pulses of the signal emitted by the clock generator 6 is independent of the speed. Via the bus system 70, the machine control 50 contains the length information for adjusting format-dependent devices on the printing press.

The scanning roller 13 is not as friction-free as possible, but with some friction so that it comes to a standstill quickly after the contact with the sheets has ended. So that the acceleration of the scanning roller 13 from standstill does not cause any damage to the surface of the paper sheets, the scanning roller 13 is constructed with a very low weight and moment of inertia and is essentially formed by a light plastic wheel.

FIG. 6 explains how the monitoring device (with the scanning device shown in FIG. 2) carries out the setting process. When the printing press is started, it is first checked on the basis of information available in the memory of the machine control 50 whether a re-adjustment of the feeler roller 13 is necessary. This is the case, for example, if, after an error, the overlapping sheets supplied by the sheet feeder have been cleared away and the build-up of a shingled sheet feeder must therefore be monitored again. If no readjustment is necessary, sheet monitoring is continued from the point at which it was interrupted.

In FIG. 6, diagram 100 shows the arrangement of overlapping sheets B, one having to imagine these sheets as running from right to left in FIG. 6. Diagram 101 shows the course of the total thickness of the sheets with a dashed line, similar to curve 81 in FIG. 5. The solid line shows the height setting of the scanning roller 13 in the sheet feed monitoring with length determination, and in diagram 102 one pure multiple sheet control. In diagram 102, the thickness curve of the sheet is again drawn in with a dashed line in the same way as in diagram 101.

The time axis runs from left to right in FIG. 6. After a start, the feeler roller 13 is moved by means of the lever 11 and the motor 22 from a basic position, which is present at the time P1, in which it is lifted off the rotating transport roller 9, to the transport roller 9. As soon as the sensor 14 emits signals which indicate the rotation of the feeler roller 13, it has touched the transport roller 9. This is the case at time P2. The voltage value supplied by the potentiometer 20 on the line 21 is now stored in the microcomputer 51 and assigned to the value O for the distance 30 there. Thereafter, the scanning roller 13 is lifted again so far from the transport roller 9 by switching on the motor 22 that it stops and therefore the sensor 14 no longer emits any signals; this is the case at time P3. The processes described so far have been completed before the first sheet reaches the scanning roller 13.

At time P4, the arrival of the leading edge of the first sheet rotates the scanning roller 13 and the sensor 14 emits signals. The front edge of the first sheet (or the time P4) must occur within a predetermined machine angle (rotational position of the machine part driving the clock generator 6); if this is not the case, the monitoring device reports that a sheet is missing (missing sheet). After the detection of the first sheet at time P4, the scanning roller 13 is raised further, until the sensor 14 no longer emits a signal; this is the case at time P5. Now the signal supplied by the potentiometer 20 at this time is read by the microcomputer 51 and stored. The microcomputer 51 determines the taking into account the characteristic of the potentiometer 20 and the pitch of the thread of the rod 18 Sheet thickness d and now uses a stored table to determine the pressing force with which the motor 32 is to press the lever 11 in the illustration in FIG. 2 in the counterclockwise direction, that is to say against the sheet or against the stop 27, and the associated motor current. In addition, a new distance 30 is calculated, which is slightly smaller than twice the sheet thickness 2d, and this new distance is set. This process is completed at time P6.

The distance mentioned, which corresponds to the simple sheet thickness d plus a tolerance Td (less than d), is selected so that, on the one hand, irregularities in the printing material (paper sheet) do not lead to the scanning roller 13 rotating, but on the other hand the starting edge of the next sheet at the time P7 is clearly recognized. First of all, the microcomputer 51 checks again whether the start edge of the next sheet arrives at a time P7 within a permissible machine angle range; Thereafter, the scanning roller 13 is raised by the control of the microcomputer 51 by the amount of a sheet thickness d. This process is completed shortly after time P7. When the scanning roller 13 is raised at the times P4 and P7, a memory location in the microcomputer 51 is increased by the amount 1, so that the number n of sheets overlapping one another at a specific time is also known.

At time P8, which corresponds to the expected leading edge of the third sheet in FIG. 6, the operating mode preselected by the operator, namely either a multiple sheet control (illustration 102) or the sheet feed monitoring with sheet length measurement (illustration 101) is first determined by the microcomputer 51, and then the Adjustment of the intermediate space 30 during the process according to illustration 101 to (nl) xd + Td at time P9 or in illustration 102 to the value nxd + Td.

The transport path of the sheets between the times P7 and P8 corresponds to the constant length S2 in FIG. 5, which is predetermined by the type of sheet feeder 2.

From the fact that the scanning roller 13 is not rotated at the time P8, the device recognizes that there is again only a double overlap.

The time P9 is a very short time after the time P8. In sheet feed monitoring with sheet length measurement (illustration 101), the scanning roller 13 thus comes into contact with the upper side of the scaled sheet a very short time after the front edge of the third sheet B has reached it in FIG. 6 and is rotated. The rotation stops at time P10 because the overlap of two sheets ends here. The control device can now calculate the arc length from the advance of the arc between the times P8 and P10 measured overlap length. If it is not possible to lower the scanning roller 13 quickly enough after the time P8, the overlap following the time P10 is expediently used to measure the length of the overlap. The device can continuously determine the arc length.

6 shows only double overlaps. If more than two sheets overlap at the same time, the sheet length can still be changed during sheet feed control (illustration 101) should not be calculated at time P10, but only at a later time. The arc length can therefore only be determined after the point in time at which the maximum number of overlaps occurs.

In the sheet feed control (illustration 101), the variables S1, S2, S3, n shown and described in FIG. 5 are continuously measured or calculated. Since the signal output of the sensor 14 on the feeler roller 13 is influenced both in the case of missing sheets and in the case of multiple sheets and extreme sheet displacements which impair the function of the printing press, these errors are reliably detected and reported. Each time two sheets overlap, the scanning roller 13 is rotated in this operating mode.

If the sheet is missing, the operator is signaled a missing sheet by means of the light-emitting diode display 58 and, if this message is forwarded to the machine control system 50, an interruption in the sheet supply is effected. The sheets already on the feed table 5 are then printed and the printing is then stopped. The error message is canceled by a start command from the operator and the build-up of the scaled sheet feed is monitored again, as described above.

Too much conveyed sheets (multiple sheets) are also visually displayed and reported to the machine control 50. The defective point in the sheet stream, that is to say in the successive sheets, is now transported further after the sheet feeder has been parked until the multiple sheet is a point that is easily accessible to the operator has reached and the machine has just finished printing. The printing process is then set by the machine and the excess sheet fed can be easily removed by the operator. After starting the printing machine, the structure of the shingled sheet feed is checked again.

In the case of pure multiple sheet control according to illustration 102, the sensor 14 normally does not emit a signal because the scanning roller 13 does not come into contact with the sheet even in the area of overlaps. Therefore, by monitoring a rotation of the scanning roller 13 on the basis of the output signal from the sensor 14, only too much conveyed sheets and long creases in the printing medium which impair the function of the printing machine are detected when these creases cause the scanning roller 13 to rotate as well.

Shortly after time P10, i.e. When the rear edge of the second sheet in FIG. 6 is recognized, the device has for the first time ascertained all the data which are necessary for the described functional sequences of the device for sheet feed monitoring with sheet length measurement (illustration 101).

In the multiple sheet control (illustration 102), the device has determined all the data necessary for the functional sequences required shortly before the point in time P8, where it is recognized from the absence of an increase in thickness that only two overlaps occur.

The microcomputer 51 knows how many pulses of the signal supplied by the clock generator 6 occur until a sheet placed by the sheet feeder arrives at the scanning roller 13. If the sheet feeder is switched off while the printing machine 1 is running, but the sheets present on the feed table 5 are still to be printed, the total thickness of the sheets passing under the scanning roller 13 gradually decreases. So that this degradation of the shingled sheet supply can also be reliably monitored, the scanning roller 13 is used by the microcomputer 51 when the shutdown signal of the sheet feeder, whose standstill is known to the microcomputer 51, the scanning roller shortly after the trailing edge of a sheet passes by an arc thickness lowered. If the sheets are still properly positioned and fed, the scanning roller 13 is not rotated. However, if one of the sheets has folds or a multiple sheet occurs, this is recognized by the scanning roller 13, which is rotated in this case. A missed sheet cannot be detected at this stage of the scan; however, the missing sheet must have been recognized beforehand, that is to say the scanning roller has scanned the leading edges of the sheets.

Claims (11)

1. Monitoring device for the shingled sheet feed to printing presses, with a scanning roller (13) rotatably mounted on a support above a base of the shingled sheet, the support being adjustable by an actuator such that the scanning roller is only rotated when a certain one Number of sheets lying one above the other, with a sensor (14) interacting with the scanning roller (13), an intermediate roller (40) movable substantially perpendicular to the plane of the sheets transversely to their axial direction can be provided between the scanning roller and the support,
characterized in that the scanning roller (13) is rotatably mounted indefinitely, that the sensor (14) is designed such that it detects every rotary movement of the scanning roller (13) that a device for measuring the distance between the scanning roller (13) and the Intermediate roller (40) from the base of the shingled sheets is provided, that a control device is provided, which is coupled to the sensor, the measuring device and the servomotor, that a device is provided for generating a signal which is characteristic of the angle of rotation of the printing press and which is the Control device is supplied, and that the control device is designed such that it monitors the scale structure. 2. Device according to claim 1, characterized in that the control device is designed such that it automatically determines the arc length. 3. Apparatus according to claim 1 or 2, characterized in that the control device is designed such that it determines the thickness of the sheet and the scanning roller when passing through the first sheet under the scanning roller (13) or intermediate roller (40) by height adjustment of the carrier (13) or intermediate roller (40) to a height that is greater than the thickness of a single sheet, but less than twice the sheet thickness. 4. Device according to one of the preceding claims, characterized in that the control device is designed such that it evaluates the signal characteristic of the angle of rotation of the printing machine during the presence of the signal of the sensor (14) indicating the rotation of the scanning roller (13) thereby determining the length of the overlap area. 5. Device according to one of the preceding claims, characterized in that a force generating device is provided which loads the scanning roller (13) or intermediate roller (40) with a force adjustable by the control device. 6. The device according to claim 5, characterized in that the force generating device is an electric motor (32). 7. Apparatus according to claim 5 or 6, characterized in that a memory for storing the force to be exerted by the force generating device is provided at least in dependence on the paper thickness. 8. The device according to claim 7, characterized in that the control device is designed such that it automatically adjusts the force to a value contained in the memory. 9. Device according to one of the preceding claims, characterized in that the control device compares the signal supplied by the sensor (14) and the signal characteristic of the speed of the printing press (1) with one another and emits a fault signal in the event of deviations which exceed a predetermined dimension . 10. Device according to one of the preceding claims, characterized in that the signal characteristic of the speed of the printing press (1) is a clock signal, and in that the control device is designed such that it detects the occurrence of the leading edge of a sheet on the scanning roller (13). compares with the phase of the clock signal and emits a fault signal in the event of an impermissible deviation. 11. Device according to one of the preceding claims, characterized in that the control device is designed such that it monitors the scale reduction in the presence of a signal indicating the switching off of the sheet feeder.

Images