EP0121803A1 - Device for repeatedly separating and transferring the uppermost sheet of a stack of sheets - Google Patents

Abstract

In order to increase the separation security of the separating device and to initiate the transport of the separated sheet or sheet-shaped object to the subsequent treatment devices in a simple manner at the same time as the separation, the sheet is detected by means of a movable suction mouthpiece, which follows a periodically changing vacuum and overpressure phases the connecting line generating, valveless pump (13) is connected. The direction of movement of the movable suction mouthpiece (6) runs at such an angle (β) with respect to the direction of gravity (G) that the resultant of the stroke movement occurring during the negative pressure phase and the falling movement of the sheet arising during the positive pressure phase is in the intended transport direction (F) pointing component receives. To bridge larger stack heights, an additional adjusting device for the movable suction nozzle or a level-controlled stacking table (2, 4) is provided. The stacking table (2) is preferably inclined by a certain angle (α) with respect to the horizontal in order to increase either the separation reliability of the separation or the transport speed of the sheet.

Description

The invention relates to a device for separating and transporting the uppermost sheet of a stack of sheets or sheet-shaped objects by means of a movable suction mouthpiece, in which the negative pressure which causes the suction of the sheet simultaneously controls the movement of the suction mouthpiece which is mounted in a guide in a longitudinally displaceable manner.

A device of this type is the subject of German Utility Model 1 782 267. However, in order to generate a transport movement in the direction of the subsequent transport rollers, a separate blowing nozzle is required, the air flow of which can capture several of the top sheets of the stack and thereby disrupt the separation process.

It is the object of the present invention to further develop a device of the type mentioned at the outset in such a way that the safety of the separation process is increased, and that the movable suction mouthpiece can, in addition to the separation, also initiate the transport of the sheet to the subsequent transport rollers in a simple manner.

According to the invention, the object is achieved by the features listed in the characterizing part of claim 1.

In this arrangement, the movable suction mouthpiece first performs a lifting movement which lifts the sheet to be separated from the stack. This stroke movement is followed by a pulsating movement of the suction mouthpiece, which, on the one hand, causes the suction mouthpiece to be shaken off unintentionally. attracted double sheet causes and on the other hand by the periodic change in certain directions lifting and falling movements of the sheet initiates its transport to the subsequent transport rollers. The pulsating movement of the suction mouthpiece can be increased by increasing the area of attack of the periodically changing air pressure in the connecting line between the suction mouthpiece and the valveless pump by means of a membrane connected to the suction mouthpiece.

To bridge larger stack heights, an additional adjustment device for the movable suction nozzle, provided with an external drive, can be used or a level-controlled rising table can be provided for the stack.

A particularly separable embodiment of the separating and transport device according to the invention is obtained if the stacking table is inclined against the transport direction and is provided with rear stacking stops. In this way, very thin, air-permeable sheets as well as plastic films adhering to each other due to electrostatic charges can be separated equally reliably.

The transport speed in the direction of the subsequent transport rollers can be increased by using a stacking table inclined in the transport direction with front stacking stops. This embodiment favors the feeding of sheets during operation.

In all embodiments of the separating device according to the invention, it is possible for the conveyed sheet to stand upright, in a known manner, depending on the operating phases of a following device. clocked transport roller pair or to put on a side stack stop, without significant frictional forces or wear caused by friction occurring on the movable suction nozzle and the conveyed sheet.

• Fig. 1 einen Schnitt durch eine erfindungsgemäße Vereinzelungseinrichtung in halbschematischer Darstellung,
• Fig. 2 das Bewegungsdiagramm des vom Saugmundstück erfaßten Blattes,
• Fig. 3 den zeitlichen Verlauf der Saugmundstückbewegung,
• Fig. 4 eine andere Ausführungsform der erfindungsgemäßen Vereinzelungsvorrichtung,
• Fig. 5 eine Saugmundstückanordnung zur Abnahme von groß- oder verschiedenformatigen Blättern,
• Fig. 6 ein mit einer Membrane verbundenes, bewegliches Saugmundstück, und
• Fig. 7 einen mit einer Membranpumpe zu einer Baueinheit vereinigten Saugabnehmer.

Details of the invention emerge from the subclaims and the description, in which an exemplary embodiment is discussed below with reference to the drawing. Show it

• 1 shows a section through a separating device according to the invention in a semi-schematic representation,
• 2 shows the movement diagram of the sheet gripped by the suction mouthpiece,
• 3 shows the time course of the suction nozzle movement,
• 4 shows another embodiment of the separating device according to the invention,
• 5 shows a suction nozzle arrangement for the removal of large or different-sized sheets,
• Fig. 6 is a membrane connected to a movable suction mouthpiece, and
• Fig. 7 a combined with a membrane pump suction unit.

According to FIG. 1, a stacking table 2 for a sheet stack 3 is arranged in a device frame 1. The stacking table 2 is inclined at an angle α with respect to the horizontal and has at its rear end a stacking stop 2a, which is located on the Place stacked sheets 3a under the force of gravity. It is designed as a so-called riser table, which can be adjusted automatically in the direction perpendicular to the stack surface by means of screw spindles 4 in a known manner as a function of a stack sensor not shown in the figure, so that the stack surface is always the level indicated by the line H in the figure occupies.

The top sheet 3a of the stack 3 is under the action of its own weight and a light pressure spring 5, a movable suction nozzle 6. The suction mouthpiece 6 is plugged onto a mouthpiece 7a which is formed at the lower end of a movable piston 7 and which has a central bore 7c. The piston 7 is mounted for longitudinal movement in a guide cylinder 8, into which a stop screw 9 engaging in a recess 7b of the piston 7 is screwed. The guide cylinder 8 is inserted into a holder 10 fixed to the device and is closed at its upper end by means of a connection piece 11 provided with a central bore 11a and screwable into the guide cylinder 8, which at the same time serves as a counter-bearing for the pressure spring 5 arranged inside the piston 7.

On the connector 11, a connecting line 12 is plugged, which connects the inside of the guide cylinder 8 with a valve-less diaphragm pump 13. The membrane 16 of the membrane pump 13 is between one Upper part 14 and a lower part 15 clamped and connected to a crank rod 17 by means of a screw 16a. The crank rod 17 is set in a periodic movement by an eccentric 18 mounted in the lower part 15 of the diaphragm pump and driven in the arrow direction B by a drive motor (not shown in the figure). Of course, instead of the diaphragm pump shown in the figure, a valveless piston pump or another pump arrangement suitable for generating a periodically changing overpressure and underpressure can also be used.

In addition to a tubular connecting piece 14a for the connecting line 12, the upper part 14 carries a pipe piece 14b which serves as a ventilation line and which can be closed by means of a hemispherical valve body 19 made of an elastic material. A peg-shaped extension 19a of the valve body 19 is inserted into a corresponding hole in a raised tab 20a of a two-armed rocker arm 20, which is under the action of a leg spring 21 which tries to turn it counterclockwise and which thereby causes the valve body 19 to open the pipe section 14b creates. An arm 20b of the rocker arm 19 interacts with an actuating lever 21 which extends through an opening la of the device frame 1. The actuating lever 21 is controlled by the control device of the device following the separating device according to the invention, not shown in detail, for example electromagnetic means, in the cycle in which the sheets are to be separated, whereby a Opening the valve 14b, 19 causes an immediate interruption of the separation and transport process.

Finally, seen in the conveying direction F of the individual sheets, 2 transport rollers 22 and 23 are arranged behind the stacking table and are supported on shafts 24 and 25. The transport rollers 22 and 23 can either rotate continuously in the direction indicated by the arrow or be driven intermittently in the cycle required for the subsequent processing machine. By means of the last-mentioned clocking e.g. in the case of a copier, the correct application of the copy carrier to the recording cylinder can be controlled in a known manner. The transport rollers 22 and 23 are surrounded by guide plates 26 and 27 for the sheets to be transported.

Figures 2 and 3 show the sequence of movements of the suction mouthpiece 6 and the sheet 3a gripped by this mouthpiece. Accordingly, the movable suction nozzle 6 is initially under the action of the pressure spring 5 on the top sheet of the stack 3. After closing the vent valve 19 (Figure 1). or, if no such venting valve is provided, after the pump 13 has started, the sheet 3a is attracted to the suction mouthpiece, closing the bore 7c of the piston 7 in the manner of a check valve. In the interior of the guide cylinder 8, a negative pressure is created, which also affects the rear end faces of the piston cross section 7d (FIG. 1), as a result of which the Piston 7 is raised against the effect of its own weight and the force of the pressure spring 5 starting from the stacking level H _o by a distance H ₁ corresponding to the volume ratios of the guide cylinder 8 and the diaphragm pump 13.

• - Volumenverhältnis der Pumpe, der Zylinderführung und der dazwischenliegenden Luftleitungen,
• - Trägheit des beweglichen Saugmundstückes, sowie Art und Stärke darauf wirkenden Rückstellkräfte (z.B.Andruckfeder 5),
• - Pumpfrequenz,
• - relativer Einfluß des am Saugmundstück herrschenden Unterdruckes auf das Ansaugen des Blattes und das Heben des Kolbens.

During the following overpressure phase of the diaphragm pump 13, the piston 7 cannot follow the pump movement without inertia, which results in volume differences between the pump stroke and the piston stroke, which temporarily result in an overpressure in the underpressure due to the weight of the piston and the action of the pressure spring 5 Generate connecting line 12. This leads to a blowing out of air through the check valve formed by the sheet 3a and the movable suction mouthpiece 6, which, in conjunction with the inertia of the movable suction mouthpiece, causes the piston 7 on the one hand no longer to reach its stack-side end position during the subsequent strokes of the diaphragm pump 13 , and on the other hand is no longer raised beyond the full stroke distance H ₁ corresponding to the volume ratios of pump 13 and guide cylinder 8. Rather, after a short transition period, a periodic piston movement occurs with the amplitude A essentially constant during the entire switch-on time t _e , which moves the suction mouthpiece 6 back and forth between the stroke heights H _min and H _max at a frequency corresponding to the pump frequency f. The amplitude A or the size of H _max and H _min depend in particular on the following factors, the suitable choice of which influences them in the desired sense

• - Volume ratio of the pump, the cylinder guide and the air lines in between,
• - Inertia of the movable suction mouthpiece, as well as the type and strength of the restoring forces (e.g. pressure spring 5),
• - pump frequency,
• - Relative influence of the negative pressure prevailing at the suction mouthpiece on the suction of the sheet and the lifting of the piston.

A movement characteristic suitable for the removal of paper sheets of different basis weights and of thin plastic foils was achieved, for example, with the dimensions customary in known telescopic suction devices when using a light pressure spring with a flat characteristic and with a lifting height H _max of approximately 10 to 20 mm with a pumping frequency of approximately 20 to 30 Hz achieved.

It has also been found that both the suction and the separation security of the separating and transport device according to the invention can be improved by using a suction mouthpiece, which is equipped in the manner shown in the figures with the largest possible elastic suction plate 6a (FIGS. 1, 2, 6.7). This suction plate 6a closes due to its elasticity the top sheet of the Stack even in the event of unevenness and angle differences and offers a large area for the attacking negative pressure. Even in the cases in which there is initially a small distance between the suction plate 6a and the uppermost sheet of the stack, due to the air flowing in under the extended suction plate at a relatively high speed, there is in most cases sufficient underpressure to initiate the suction process.

The relative influence of the air pressure prevailing in the connecting line 12 on the lifting movement of the suction mouthpiece 6 can, as will be explained in more detail below, be achieved by increasing the effective piston area 7d or by switching a membrane connected to the piston 7 into the airway .

As can be seen in particular from FIG. 2, the above-described movement characteristic of the movable suction device 6 leads to the uppermost sheet 3a of the stack 3 first being lifted off the stack by the distance H ₁ . It then alternately performs falling movements in the direction of gravity G and stroke movements in the direction of movement H of the movable suction mouthpiece 6 in the rhythm of the pump frequency. If the suction guide is inclined by a suitable angle β with respect to the direction of gravity G, the two movements above result in a movement in the direction of conveyance F.

In the examples shown in FIGS. 1 and 2, the conveying direction F is inclined by an angle α with respect to the horizontal. This inclination of the conveying direction F, which essentially corresponds to both the inclination of the lower surface of the suction mouthpiece and the inclination of the stack surface, favors the retention of the sheets in the stack by the action of gravity and thereby increases the separation security of the separating device.

A particular advantage of the separating device according to the invention is that the conveyed sheet is without frictional connection with the suction nozzle 6 during its lifting and falling movements as described above. It is therefore possible to move or hold the separated sheet virtually without friction by introducing additional forces against the direction of movement specified by the suction mouthpiece, without switching off the pump. This is important in the often practiced application of the isolated sheet against a standing pair of suction rolls. On the other hand, it is also possible, as will subsequently be shown with reference to FIG. 4, to convey sheets of different formats by means of a single suction cup placed in a suitable manner and to place them on a lateral guide during the transport process.

According to FIG. 4, sheets 3a of different formats lie on a stacking table. The suction nozzle 6 is placed so that it alternately each of a rear stack stop 2a and a side Stack stop 2b created sheet formats 3a can capture. Its conveying direction F 'is rotated by such an angle β with respect to the actual conveying direction F that a conveying component F "directed towards the lateral guide 2b is created. The conveyed sheet is therefore, regardless of its external dimensions, against the lateral guide during the entire transport process 2b created and fed to the conveyor rollers 22, 23 without tilting.

As can also be seen from FIG. 4, in addition to the suction nozzle 6 to bridge a longer transport path to the first pair of conveying rollers 22, 23, a further suction nozzle 6 ^{1 can be} arranged. In addition, it is possible to arrange a plurality of suction mouthpieces, such as suction mouthpieces 6 and 6 ", next to one another for conveying wider formats.

FIG. 5 shows an embodiment of the separating device according to the invention, in which the stacking table 28 is inclined by an angle α with respect to the horizontal in the transport direction. In this case, the stack stop 28a is arranged in front of the sheet stack 3. The suction cup 29 with the suction mouthpiece 30 is fastened to a pivotable carrier 31 which is mounted on an axis 32 fixed to the device. The carrier 31 is under the action of a tension spring 33 which tries to pivot it counterclockwise and thereby places it against a stop 34 fixed to the device. Due to this pivoting movement, the suction nozzle 30 is in the

Hibernation lifted off the stack surface. During this operating phase, it is possible to add further sheets to the stack 3, a guide plate 35 attached to the carrier 31 preventing the sheets being pushed behind the suction mouthpiece 30 from getting caught. In addition, the part of the suction mouthpiece 30 which projects beyond the guide plate 35 in the idle state is provided with an insertion bevel 30a.

The pivoting movement of the carrier 31 serves to enlarge the initial lifting movement of the suction mouthpiece. Insofar as this large initial stroke is not required, H _min (FIG. 3) can be chosen to be correspondingly smaller, as a result of which there is greater freedom in the selection of the variables listed above which influence the stroke of the suction nozzle.

A lifting magnet 36, which is connected to an arm 31a of the movable carrier 31 by means of a pull rod 37, serves to initiate the positioning movement. The lifting magnet 36 is actuated by means of suitable control means shortly before the pulsating suction device 29, 30 is switched on and is switched off again shortly after the suction device is switched on. The connecting line 38 to the suction pickup 29, 30 arranged on the pivotable carrier 31 is guided in a known manner through the hollow pivot axis 32.

In this case, the inclination β of the stroke direction H with respect to the direction of gravity G is chosen such that the stroke movement together with the tilting movement of the carrier 31 essentially only the isolated sheet separates from the stack and lifts over the stack front stop 28a, while the movement component of the separated sheet 3a pointing in the transport direction F is derived predominantly from the falling movement in the direction of gravity G. By means of this transport movement, the sheet is fed to a pair of transport rollers 22, 23 which is arranged on a guide track formed by guide plates 26, 27.

According to FIG. 6, a membrane 39 is attached to the upper end of the tubular piston 37 carrying the movable suction nozzle 6 by means of an annular nut 37a. The membrane 39 is inserted into the upper, can-like part 40a of a cylinder guide 40 and covered by means of a cap 42 fastened to the cylinder guide 40 by means of screws 41, to which the suction air line 12 is connected. The space enclosed between the membrane 39 and the cap 42 is thereby connected to the valve-less pump, while the space located below the membrane is connected to the outside air through ventilation holes 40b.

In this arrangement, the pump pressure acts on a much larger area than the cross-sectional area of the piston 37, so that the vacuum required for the suction nozzle 6 has a much greater effect on the movement of the piston 37. As already explained above, the movement characteristic shown in FIG. 3 can be influenced in the sense that the air pressure prevailing in line 12 has a greater effect on the movement of the suction mouthpiece.

According to FIG. 7, an annular body 44 is arranged in a holder 43 fixed to the device, in which two membranes 45 and 46 are inserted. The lower membrane 45 is held in the ring body 44 by means of a screw ring 47, the upper membrane 46 by means of a screw cap 48. A tubular support 50 for the movable suction mouthpiece 6 is fastened to the membrane 45 by means of a ring nut 49. The membrane 46 is connected by means of a screw 51 to a bolt-shaped magnet armature 52 which is immersed in a magnet coil 53 inserted into the screw cap 48. The solenoid 53 is connected by means of lines 54 and 55 to an alternating current generator (not shown in the figure) which supplies it with alternating current of the frequency required for the operation of the suction pickup in the cycle required for the separation and transport of the sheets in the stack 3. In this case, the membrane 46 forms the membrane pump required for the operation of the movable suction mouthpiece 6, which can be inserted into the device as a whole unit together with the suction customer or can be removed from the device for maintenance purposes. Of course, the tubular support 50 for the movable suction nozzle 6 could also be guided in a cylinder guide in the manner shown in FIG.

Claims (16)

1.Device for separating and transporting the uppermost sheet of a stack of sheets or sheet-shaped objects by means of a movable suction mouthpiece, in which the negative pressure causing the suction of the sheet simultaneously controls the movement of the suction mouthpiece which is longitudinally displaceable in a guide, characterized by the following features: a) The movable suction mouthpiece (6,30) is connected to a valveless pump (13), which generates periodically changing vacuum and overpressure phases in the connecting line (12) between the suction mouthpiece and the pump, b) the direction of movement (H) predetermined by the guide ((8, 40, 45) of the movable suction mouthpiece (6.30)) is inclined at such an angle (ß) against the direction of gravity (G) that the resultant during the Vacuum phase caused by the movable suction nozzle (6,30) lifting movement of the sheet (3a) and during the overpressure phase caused by the gravity acting on the sheet (3a) falling into the intended Transport direction (F) of the sheet-pointing component receives. 2. Apparatus according to claim 1, characterized in that the suction mouthpiece (6,30) on a in a with the valve-less pump (13) connected guide cylinder (8,40) guided, with a central bore (7c) provided piston (7, 37) is attached. 3. Apparatus according to claim 2, characterized in that on the piston (7) engages the suction mouthpiece (6) on the sheet (3a) pressing spring (5). 4. Device according to one of claims 1 to 3, characterized in that the drive of the movable suction mouthpiece (6) by a in the connecting line (12) to the valveless pump (13) lying membrane (39,45) is formed. 5. The device according to claim 4, characterized in that the movable suction mouthpiece (6) is attached directly to the membrane (45). 6. Device according to one of the preceding claims, characterized in that the valveless pump (13) is designed as a diaphragm pump (14-18). 7. The device according to claim 6, characterized in that a magnet-driven diaphragm pump (46,52,53) is arranged on the guide (43,44,45) for the movable suction mouthpiece (6). 8. Device according to one of the preceding claims, characterized in that the stack-side end of the suction mouthpiece (6) is designed as an elastic support plate (6a). 9. Device according to one of the preceding claims, characterized in that several suction mouthpieces (6, 6 ', 6 ") arranged next to or behind one another in the transport direction are provided for detecting sheets of different sizes or formats. 10. Device according to one of the preceding claims, characterized in that the conveying direction (F ") at least one of the suction mouthpieces (6, 6 ', 6") is rotated by such an angle (γ) relative to the intended transport direction (F) that In addition to the movement component in the transport direction, a movement component (F ") directed against a stop (2a) arranged laterally on the transport path is produced. 11. Device according to one of the preceding claims, characterized in that the working phases of the movable suction mouthpiece (6) can be controlled by means of a valve (19) switched on in a vent line (14b) of the suction mouthpiece. 12. Device according to one of the preceding claims, characterized in that an adjusting device (31-36) for the movable suction mouthpiece (30) is provided. 13. The apparatus according to claim 12, characterized in that the adjusting device (31-36) is driven by an electromagnet (36). 14. Device according to one of the preceding claims, characterized in that a level-controlled rising table (2,4) is provided. 15. Device according to one of the preceding claims, characterized in that the stacking table (2) is inclined against the sheet transport direction (F) and is provided with stacking stops (2a) at its rear end. 16. Device according to one of the preceding claims, characterized in that an in Sheet transport direction (F) inclined stacking table (28) is provided, which carries stacking stops (28) at its front end.

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