EP0913352A2 - Buckling folder and method for registration control of a buckling folder - Google Patents

Abstract

The folding mechanism has a first folding roller (12), a pair of counter-rotating folding rollers (14,16) and an adjustable folding pocket (20), with evaluation of the supplied sheet length between the detection of the sheet entry and the detected deflection of at least one of the folding rollers upon formation of the fold. The deflection of the folding roller may be detected via a bearing lever and associated expansion measuring strips, or a piezoelectric sensor. A register regulation method for an envelope folding mechanism is independently claimed.

Description

The invention relates to a pocket folder with a first folding roller and two further, counter-rotating, fold-forming Folding rollers and an adjustable folding pocket. The invention further relates to a procedure for register regulation of a Pocket folding unit.

Pocket folders are known in the prior art. Three, in essentially arranged on the corner points of a right-angled triangle Folding rollers and a folding pocket form a pocket folder. The convey two first folding rollers arranged vertically one above the other the incoming sheet into the folding pocket up to the pocket stop, the is freely adjustable. The bow is made on the paper texture matched running speed in the bag. When bumping the front edge of the sheet and simultaneously transporting it further of the sheet is formed between the three folding rollers in the Stowage space a sagging crease that is horizontal by the two juxtaposed counter-rotating folding rollers is detected. As the sheet passes through the rollers, it forms then the fold. The folding process takes place continuously in a pocket folder and is not tied to any cycle sequence, resulting in large folding rates can be achieved. Can in a pocket folding machine several pocket folding units can be provided. According to the continuous Sheet thickness, the folding roller spacing must be set. This is done by mounting the folding rollers on a two-armed lever, the opposite end of the folding roller from an adjusting screw is applied. Also the fold pocket stop, the width the folding pocket as well as the position of the pocket mouth and pocket lips to the stuffer box must be based on the paper quality used and the Sheet format can be set. They also need these settings can also be carried out when the air humidity changes, because this changes the stiffness of the paper. Also changed Production speeds cause a changed deformation of the Sheet in the folding pocket or in the stowage space, so that the position of the Fold break moves on the sheet and the folder may be readjusted must become. The positional deviation of the fold break on the sheet can only be determined on the finished folded sheet. So far there there is no way to determine the timing of the fold formation and thus deviations in the fold break position on the sheet already during the continuously running production process.

Even if such a positional deviation of the fold break is found the required settings had to be made manually become.

The invention is therefore intended to create a pocket folding unit with which the determination of the time of the fold formation is made possible is. In addition, a pocket folder should be specified, which allows the position of the fold break on the sheet to be regulated. Furthermore, a method for register control of a pocket folding unit is intended be specified, the constant position of the fold break on the sheet with changed production speed or paper stiffness guaranteed.

a) Mittel zur Erfassung des Bogeneinlaufs,

b) Mittel zur Erfassung der Auslenkung wenigstens einer der falzbildenden Falzwalzen bei der Falzbildung und

c) Mittel zur Bestimmung der zwischen Bogeneinlauf und Falzbildung geförderten Bogenlänge auf.

According to the invention, a pocket folding mechanism with a first folding roller and two further counter-rotating folding forming folding rollers and an adjustable folding pocket is provided. The pocket folder shows

a) means for detecting the sheet inlet,

b) means for detecting the deflection of at least one of the fold-forming folding rollers during the fold formation and

c) means for determining the length of the sheet conveyed between the sheet inlet and the fold formation.

A reference point is created when the sheet entry is recorded and enables the determination of target values. The fold formation takes place exactly from the time at which the sagging crease is grasped by the two fold-forming folding rollers. For folding the fold-forming folding rollers exert pressure on the compression fold. Thereby the folding rollers are deflected to a small extent. The capture allows the deflection of at least one of the fold-forming folding rollers hence the exact determination of the point in time of the fold formation with several fold breaks. By the between the sheet inlet and fold formation is determined, a setpoint is available Available, which indicates a proper fold formation. The The fold-forming folding rollers can be deflected by measuring methods that measure the movement directly, e.g. Way, speed or Acceleration measurement, or by measuring methods, which by the measure the movement triggered reactions, e.g. Force or deformation measurement on live components.

In a development of the invention it is provided that the means for Detection of the folding roller deflection on at least one bearing lever Folding rollers have a strain gauge arrangement. The elastic Deformation of the bearing lever and the reaction forces when deflected the folding roller can thus directly without moving parts electrically detected and thus processed in a simple manner become.

As a further training measure it is provided that the funds for Detection of the folding roller deflection at least one, on a bearing lever of the folding roller arranged piezoelectric sensor. For example, acceleration can be achieved with piezoelectric sensors or by further processing the measurement signals, the path of the bearing lever the folding roller can be detected.

In an advantageous development of the invention, the Means for detecting the folding roller deflection at least one optical sensor. The detection of the folding roller deflection can thereby, for example, via a light barrier or also via the Reflection of a light beam on the bearing lever.

In a development of the invention it is provided that the means for Detection of the sheet inlet have at least one optical sensor. An optical sensor enables the reliable in a simple way and exact detection of the sheet entry, for example by the changing reflection or transmission at the sheet entry is detected.

It is further envisaged that the means for determining the between the sheet inlet and the formation of folds Pulse generator, which is assigned to a folding roller, and a counting device exhibit. If the size of the folding roller is known, the Number of pulses emitted by the pulse generator that by one Circumferential point of the folding roller covered path and thus the funded Arc length can be determined. Since in general all three folding rollers of the The folder can rotate at the same peripheral speed Pulse generator on each of the folding rollers or on the drive train of the Folding unit can be arranged. Magnetic inductive, optical sensors or sensors using the Hall effect. As Counting device can be a commercially available discrete electrical Circuit or an integrated circuit can be used.

According to an advantageous development of the invention, furthermore optical sensors for recording the beginning of the print image on a incoming arch provided. This embodiment of the invention is particularly advantageous if, for example, a brochure or a prospectus is to be produced in which the printed image is relative is shifted to the beginning of the curve or fluctuates. The fold break must such sheets must be placed exactly with respect to the printed image, otherwise in the event of fluctuations between the beginning of the sheet and the beginning of the printed image, the margin is sometimes cut away. The capture of the beginning of the print image is in a simple way with a the transmission or reflection of the Arch-measuring optical sensor possible.

It is also provided that the adjustable folding pocket at least has an electrically activatable actuating device and a Control unit is provided, which detects the signals of the means of the sheet inlet, the means for detecting the deflection at least one of the folding rollers in the fold formation and the means for determination processed the length of the sheet conveyed between the sheet inlet and fold formation and the electrically activated actuating device of the folding pocket controls. Through these measures is about the display of the fold break displacement on the bow created the opportunity automatically compensate for a change in the position of the fold break. By the control of the electrically activatable control device Folding pocket can be the length of the arc section inserted into the folding pocket be influenced during the formation of the compression fold. This can change the deformation of the arch during the upsetting process, for example through a higher production speed or a changed paper stiffness can be compensated. As actuators can use servomotors with a potentiometer or stepper motors can be provided.

It is also advantageous that the control unit continues to do so Signal from the sensor for recording the start of the printed image processed. Even if the print image deviates on a sheet, the inclusion of the signal of the print image sensor the exact location of the Fold break can be ensured. Defective end products will be thereby avoided.

In a further development of the invention it is provided that the electrical activatable actuating device moves the folding pocket stop. By moving the fold pocket stop, it is inserted into the fold pocket insertable arc length changed, causing a changed deformation of the sheet in the stowage area or in the folding pocket can. It is also possible to adjust the pocket stop diagonally for the direction of insertion of the folded sheet into the folding pocket. This can For example, compensates for a printed image that is crooked on a sheet become.

It is also provided that an electrically activatable actuating device the folding pocket width is adjusted. At higher production speeds the adjustment of the folding pocket width may be necessary to prevent a wave-like deformation of the sheet in the folding pocket avoid.

It is also provided that an electrically activatable Stellinrichtrnng adjusted at least one folding pocket lip. The Adjustment of the folding pocket lip can be advantageous if the Formation of the compression fold in the compression space must be influenced.

As a further training measure it is provided that an electrical activatable actuating device for changing the compression space Pocket mouth moves. Leaves the stiffness of a sheet of paper, for example with increasing humidity, the stowage area must be scaled down to ensure proper formation of the wrinkle and thus ensuring a correct position of the fold break on the sheet.

Finally, it is particularly advantageous if the control unit has a microprocessor. This enables complex control processes can be carried out with numerous parameters. The control algorithms can also by reprogramming the microprocessor to simple Way to be changed. In addition, the automatic detection of setpoints and their possible adjustment during the production process implemented as part of a self-learning microprocessor become.

According to the invention, a method for register control is a Pocket folding unit provided according to a setpoint in a learning phase of the conveyed sheet length between sheet entry and fold formation becomes. Then, during the production process, an between Sheet entry and fold formation determined actual value of the funded Arc length by controlling the electrical actuating device on the Setpoint regulated. By such a procedure, the Learning phase changes the production speed of a folding machine without manual adjustments. Also one changed paper stiffness, for example due to changing Humidity can be compensated for by such a procedure become.

It is also envisaged that with a regulation on the beginning of the print image for each incoming sheet a difference in length between Sheet entry and start of print image is determined. A swaying Length difference between sheet entry and start of print image, one results in the fold fold position shifted with respect to the printed image, is recognized by this measure and can therefore be corrected. This is preferably done by setting the target value with the length difference between the sheet entry and the beginning of the print is corrected. By a such an approach will set the required setpoint when controlling only corrected the beginning of the printed image, so that the process steps the regulation on the sheet inlet can be maintained and just add another correction step have to.

Fig. 1a bis f eine schematische Darstellung der verschiedenen Phasen der Falzbildung in einem Taschenfalzwerk gemäß einer ersten Ausführungsform der Erfindung,

Fig. 2 eine schematische Darstellung einer zweiten Ausführungsform der Erfindung,

Fig. 3 eine schematische Darstellung der Ausführungsform der Fig. 2 bei höherer Bogengeschwindigkeit oder verringerten Papiersteifigkeit,

Fig. 4 schematische Darstellungen der zeitlichen Abstimmung der Sensorsignale der Ausführungsform der Fig. 2 bei niedriger und bei hoher Geschwindigkeit,

Fig. 5 Meßschriebe der Sensorsignale der Ausführungsform der Fig. 1 bei niedriger und bei hoher Geschwindigkeit und

Fig. 6 eine schematische Darstellung einer Falzmaschine mit einem erfindungsgemäßen Falzwerk.

Further features and advantages of the invention will become apparent from the following description and from the drawing, to which reference is made. The drawing shows:

1a to f is a schematic representation of the different phases of the fold formation in a pocket folder according to a first embodiment of the invention,

2 shows a schematic representation of a second embodiment of the invention,

3 shows a schematic illustration of the embodiment of FIG. 2 with a higher sheet speed or reduced paper stiffness,

4 shows schematic representations of the timing of the sensor signals of the embodiment of FIG. 2 at low and at high speed,

Fig. 5 measurement records of the sensor signals of the embodiment of Fig. 1 at low and at high speed and

Fig. 6 is a schematic representation of a folding machine with a folding unit according to the invention.

Fig. 1a shows a folder for processing according to the invention a sheet of paper 10. A first folding roller 12 is vertically above a second folding roller 14 is arranged. Horizontal next to the second Folding roller 14 a further, third folding roller 16 is arranged. All three folding rollers 12, 14 and 16 have the same peripheral speed on. For pulling the sheet 10, or its further transport in the folded state, the folding rollers 12 and 14 or 14 and 16 rotate opposite each other. Fig. 1a shows the time of sheet entry, too that of a conventional conveyor, for example a diagonal roller or bias belt table, conveyed sheet 10 den passes optical sensor 18 for detecting the sheet inlet.

As shown in Fig. 1b, the sheet 10 is then from the Folding rollers 12 and 14 detected and with its front end in the folding pocket 20 promoted.

In Fig. 1c it can be seen that the two folding rollers 12 and 14 the folding sheet 10 up to the folding pocket stop 22 of the folding pocket Promote 20. Since the sheet 10 now has its front end on the fold pocket stop 22 is present, he can no longer go into the Move the fold pocket 20 in.

It is consequently, as shown in FIG. 1d, within the determined by the three folding rollers 12, 14 and 16 and the folding pocket 20 Stowage space 24 compressed.

The folding rollers 12, 14 and 16 continue to rotate so that a compression fold forms within the compression space 24, which then captured by the two counter-rotating folding rollers 14 and 16 becomes.

Fig. 1e shows how the compression fold between the two folding rollers 14 and 16 is withdrawn.

The time of the fold formation is shown in FIG. 1f. In as a result, the sheet is conveyed down out of the folder. The folding rollers 14 and 16 practice one on the upset fold of the sheet 10 Force, which on the other hand also deflects the folding rollers 14 and 16 become. The folding roller 16 is at one end of a two-armed Lever 26 rotatably mounted, which can pivot about the bearing point 28. The lever 26 and thus the folding roller 16 are biased against the folding roller 14 by means of conventional adjusting and prestressing devices. At the end of the two-armed lever opposite the folding roller 16 26, a sensor 30 is arranged, which deflects the folding roller 16 detected. The sensor 30 accordingly becomes that shown in FIG. 1f When the fold is formed, a signal is sent to the evaluation unit 32 deliver. The optical sensor 18 for detecting the sheet entry is also connected to the evaluation unit 32. To between the sheet inlet and the formation of folds promoted sheet length is at the Folding roller 16 an incremental encoder 34 is provided which, depending from the rotation of the folding roller 16 pulses to the evaluation unit 32 delivers. The evaluation unit 32 has a counting device that counts the pulses emitted by the incremental encoder 34. The counting device the evaluation unit 32 is from the signal of the sensor 18, that this releases when passing the arch 10, triggered and by the signal of the sensor 30 that this at the time of the fold formation releases, stopped. In this way, the evaluation unit 32 the number of pulses counted between sheet entry and fold formation to disposal. The number of pulses can be determined by the evaluation unit 32 can also be converted into units of length of the conveyed sheet length. A display device is also provided in the evaluation unit 32, that with every folding process between sheet entry and fold formation conveyed arc length. This way there can be deviations from a target value, that of a correct fold formation corresponds to be determined immediately, without the position of the fold break must be measured on the finished folded sheet.

Fig. 2 shows a second embodiment of the invention Pocket folding unit in a schematic representation. A bow 40 will be here also conveyed and folded by three folding rollers 42, 44 and 46. There is an optical one to record the time of the sheet entry Sensor 48 provided. However, the optical sensor 48 not only detects the time of sheet entry but could also begin printing recognize on the sheet. He gives both when going through the At the beginning of the print sheet 40 as well as a signal when that Print image of the sheet 40 passes under the sensor 48. In the in the 2, the folded sheet 40 is already completely in the folding pocket 50 has been conveyed and lies on the folding pocket stop 52 on. Within the compression space 54 is by dashed lines Lines indicated a compression fold of the sheet 40, which are in the same Way as in the embodiment of Figures 1a to 1f results. The Folding roller 46 is rotatably mounted on a two-armed lever 56, the can pivot about a bearing point 58 and biased against the folding roller 44 is. The deflection of the folding roller 46 when folding is formed detected by a sensor 60, which sends this signal to a control unit 62 delivers. The sensor 60 can both above and below the Bearing point 58 may be arranged. The position indicated by dashed lines of the sensor 60 is below the bearing point 58, in particular at Use of a strain gauge arrangement, particularly advantageous. The Folding roller 46 is provided with a gear 64 which is magnetic opposite inductive sensor 66. When the folding roller 46 rotates the magnetic inductive sensor 66 therefore provides pulses, each correspond to an incremental rotation of the folding roller 46. All three Folding rollers 42, 44 and 46 have the same peripheral speed, so that the conveyed sheet length at any of the folding rollers 42, 44th or 46 can be measured. The magnetic inductive sensor 66 is also electrically connected to the control unit 62. As input signals are in the control unit 62, as can be seen in FIG. 2, consequently the signals from sensor 48 at sheet entry and start of print image, the signal of the sensor 60 when the fold is formed and the incremental one Signal of the magnetic inductive sensor 66 available. The Control unit 62 controls a servomotor 68 which stops the folding pocket 52 moves. Fig. 2 shows an operating state of the folder in which the sheet speed is low. In this Operating state is a setpoint of the conveyed sheet length between Sheet run-in or print start and fold formation determined. This Learning phase is lower before the actual start of production Speed performed.

Fig. 3 shows the folder of Fig. 2 at a higher sheet speed. The fact that the sheet 40 of the folding rollers 42 and 44 now with higher speed in the folding pocket 50 and against the folding pocket stop 52 is promoted, it deforms within the Folding pocket 50 wavy. It is located in the folding pocket 50 a larger arc length than in the state shown in FIG. 2. The compression fold will therefore be on the sheet 40 at another Form position, which causes a positional deviation of the fold break gives the bow. However, because of the larger fold length before the fold formation is promoted, the signal of the sensor 60 is only at a larger conveyed arc length, based on the signal from the sensor 48, take place. The control unit 62 therefore becomes a larger number of pulses detected by sensor 66 before the signal from sensor 60 upon formation of folds he follows. A deviation can therefore occur in the control unit 62 from the target value determined in the learning phase of FIG. 2 become. The control unit 62 therefore controls the servomotor 68 on, so that this the folding pocket stop 52 in the direction of Stowage space 54 shifts. The sheet length that can be inserted into the folding pocket is reduced so that the fold break of the next Sheet 40 are again in the correct position on the sheet becomes.

4 is the timing of the sensor signals Sensors 48, 60 and 66 of Figures 2 and 3 are shown schematically. in the 4 are the sensor signals at low speed, i.e. the state of FIG. 2 shown. At the time A, the sheet / print image sensor 48 detects the sheet entry. After two Pulses of the incremental encoder 66 is also from the sheet / print image sensor 48, the beginning of the printed image is recorded on the sheet. Thereby a correction value Lr is determined which, when regulated to the Print start of a sheet is required. At time B. the fold formation determined by the signal from sensor 60 which detects the deflection of the folding roller. Between the sheet inlet A and the fold formation B are here twelve impulses of the incremental encoder 66, so that the setpoint determined in the learning phase conveyed sheet length between sheet entry and fold formation Ls = 12 pulses is set. At time C, the transported Finally, the sensor 48 completely passes, so that its Signal returns to a low level.

The lower diagram in FIG. 4 corresponds to the timing of the sensor signals in the state shown in FIG. 3 with higher speed. At time A, the sheet / print image sensor in turn 48 the sheet entry and two pulses of Incremental encoder 66 later is the beginning of the print image on the sheet detected. This corresponds to the correction value Lr. At higher speeds the sheet deforms in the folding pocket, as in the Fig. 3 is shown wave-like, so that a greater arc length in the Fold pocket is promoted before the wrinkle can form. The Time B at which sensor 60 detects the formation of folds takes place therefore later, so that between sheet inlet A and fold formation B a Arc length Ls + ΔL is promoted. In the one shown in FIG For example, ΔL is two pulses. To these additionally funded To compensate arc length ΔL, the control unit 62 must therefore Actuate the servomotor 68 so that it engages the folding pocket stop 52 moves until the between sheet inlet A and fold formation B determined number of pulses again corresponds to the setpoint Ls.

5 shows measurement records which show the sensor signals of the folding unit shown in FIG. 1. In the diagram above the ratios at low speed are shown. At time A, the sheet sensor 18 detects the sheet entry. At the time B is the deflection of the folding roller 16 at the sensor 30 Creasing found. Time C, is also marked which the sheet 10 has completely passed the sensor 18. The impulses are supplied by the incremental encoder 34.

Analogously to FIG. 4, in the lower diagram of FIG. 5 Relationships shown at higher speeds.

6 finally shows a schematic illustration of a folding machine 70 with a folding unit according to the invention. A sheet 72 runs under a sensor 74 for detecting the sheet entry and the beginning of the print image through and is detected by folding rollers 76, 78 and 80 and folded. At the end of the folding pocket 82 there is a folding pocket stop 84 arranged, which is acted upon by a servomotor 86. In the same The folding roller is the same as in the previously shown embodiments 80 rotatably mounted on a two-armed lever 88, on which the folding roller 80 opposite end, a sensor 90 for detecting the deflection the folding roller 80 is arranged when folding. On the follow first folding unit defined by folding rollers 76, 78 and 80 further folding units. The folding roller 80 of the first folding unit is used at the same time as the first folding roller of a second folding unit. The clarity half is in the folding machine 70 of FIG. 6 only one Folding unit according to the invention shown, of course, can however, all folding units of the type provided in the folding machine 70 folding unit according to the invention.

Claims (18)

Pocket folding unit with a first folding roller (12; 42; 76) and two further, counter-rotating, fold-forming folding rollers (14, 16; 44, 46; 78, 80) and an adjustable folding pocket (20; 50; 82), characterized in that a) means (18; 48; 74) for detecting the sheet entry, b) means (30; 60; 90) for detecting the deflection of at least one of the fold-forming folding rollers (14, 16; 44, 46; 78, 80) during the fold formation and c) means (32, 34; 62, 66) are provided for determining the length of the sheet conveyed between the sheet inlet and the fold formation. Pocket folding unit according to claim 1, characterized in that the means (30; 60; 90) for detecting the folding roller deflection at least one bearing lever (26; 56; 88) of the folding rollers (16; 46; 80) have a strain gauge arrangement. Pocket folding unit according to claim 1 or claim 2, characterized in that that the means (30; 60; 90) for detecting the folding roller deflection at least one on a bearing lever (26; 56; 88) the folding roller (16; 46; 80) arranged piezoelectric sensor exhibit. Pocket folding unit according to one of the preceding claims, characterized characterized in that the means (30; 60; 90) for detecting the folding roller deflection have at least one optical sensor. Pocket folding unit according to one of the preceding claims, characterized characterized in that the means (18; 48; 74) for detecting the sheet entry have at least one optical sensor. Pocket folding unit according to one of the preceding claims, characterized characterized in that the means for determining the between sheet entry and fold formation promoted sheet length one of a folding roller (16; 46) assigned pulse generator (34; 66, 64) and a counting device (32; 62). Pocket folding unit according to one of the preceding claims, further characterized in that at least one optical sensor (48) for Detection of the beginning of the print image on an incoming sheet (40) is provided is. Pocket folding unit according to one of the preceding claims, characterized characterized in that the adjustable folding pocket (50; 82) at least has an electrically activatable actuating device (68; 86) and a control unit (62) is provided which transmits the signals of the means (48) for detecting the sheet entry, the means (60) for detecting the Deflection of at least one of the folding rollers (46) when folding and the means (66, 62) for determining the between the sheet inlet and Folded sheet length processed and processed electrically Actuating device (68; 86) of the folding pocket (50; 82) controls. Pocket folding unit according to claim 7 and claim 8, characterized in that the control unit (62) continues the signal from the sensor (48) processed to capture the beginning of the print image. Pocket folding unit according to one of the preceding claims, characterized featured. that the electrically activatable actuating device (68; 86) the fold pocket stop (52; 84) is adjusted. Pocket folding unit according to one of the preceding claims, characterized characterized in that an electrically activatable actuator Folded pocket width adjusted. Pocket folding unit according to one of the preceding claims, characterized characterized in that an electrically activatable actuating device adjusted at least one fold pocket lip. Pocket folding unit according to one of the preceding claims, characterized characterized in that an electrically activatable actuator for Changing the compression space moves the fold pocket mouth. Pocket folding unit according to one of the preceding claims, characterized characterized in that the control unit (62) has a microprocessor. Procedure for register control of a pocket folding unit according to one of claims 8 to 13, characterized in that in a Learning phase a setpoint (Ls) of the conveyed sheet length between sheet entry and fold formation is determined and during production a between the sheet inlet (A) and fold formation (B) determined Actual value of the conveyed sheet length by controlling the electrical Actuating device (68; 86) is regulated to the setpoint (Ls). A method according to claim 15, characterized in that at a regulation for the start of printing of a sheet (40) for everyone incoming sheet (40) a length difference (Lr) between sheet entry and the print image start of the sheet (40) is determined. A method according to claim 16, characterized in that Fluctuations in the length difference in the sense of a constant relation between the start of the printed image and the position of the fold break. A method according to claim 16 or 17, characterized in that that the target value (Ls) with the length difference (Lr) between sheet entry and the beginning of the print image is corrected.

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