Priority is claimed to Swiss Patent Application No. CH 01338/11, filed on Aug. 15, 2011, the entire disclosure of which is hereby incorporated by reference herein.
The invention relates to a method for regulating the speed of a cutting device, the cutting device comprising a cutter for cutting printed products and a feed device for feeding printed products to the cutter, stacks of printed products being formed from the printed products in a stacking device prior to cutting and the printed products for a stack to be formed being transported consecutively on a first conveying component of the feed device.
After binding, roughly bound printed products such as books, paperbacks, newspapers or similar products are cut to their finished dimensions on the three unbound edges. When such products are manufactured industrially, the machines required for the entire production process are usually linked in series. In this process, printed sheets are first transferred to a gathering machine and gathered by this machine to form loose book blocks. The loose book blocks are then transferred to a binding machine in which the book blocks are bound at the spine and the bound printed products are transported by conveyor belts, on which the process of curing the adhesive used in binding takes place, to a cutting device. Further machines, such as stackers, film wrapping machines and strapping machines may be located downstream of the cutting device.
Even if the speeds of the machines and conveying means can be coordinated, irregular feeds often arise, especially on the conveyor belts between the binding machine and the cutting device, because defective printed products are extracted, specimen copies are removed and returned again by operating staff or printed products become jammed in the event of deflections, for example. This leads to an irregular supply of printed products to the cutting device in particular.
A cutting device of this type with a triple cutter is disclosed in DE3302946 C2 for example. However, such devices have the disadvantage that the number of cycles which can be achieved is significantly lower than the maximum number of cycles which can be achieved by the other machines. However, this disadvantage can be offset by feeding printed products to the cutter of the cutting device cutter in stacks. During this process, the height of the stack to be cut or the number of printed products per stack is produced by what is known as a feeder located upstream of the cutter and the stack is fed to the cutter via this feeder. The feeder comprises a hopper in which the printed products supplied by the binding machine are stacked and a pushing system which pushes stacks with a defined height or a defined number of printed products from out of the bottom of the hopper and transfers them to the cutter. To prevent overfilling of the hopper, the number of cycles of the triple cutter is set slightly higher than is required by the average performance of the binding machine. This means that the filling level in the hopper constantly reduces.
To prevent the hopper from running out of printed products, the hopper filling level is monitored. The pushing process is interrupted at a minimum admissible filling level and the cutter performs one or more empty cycles until an adequate filling level is reached once more. Alternatively, the cutting device can be stopped instead of performing empty cycles. Such devices have been tried and tested when processing thick printed products. However, in the case of thin printed products, separating the printed products exactly into stacks is an imprecise process, which can lead to errors and machine downtime.
To avoid this problem, a precisely counted stack is formed in the hopper in a further cutting device embodiment and this is subsequently pushed into the cutter. During the pushing process, the supply of additional printed products must be interrupted. An accumulating conveyor can be provided for this purpose upstream of the cutting device hopper. In this type of device the number of cycles of the cutter can also be set slightly higher than the average number of cycles required to avoid overfilling the accumulating conveyor. In this process, empty cycles can be generated from time to time or the cutter can be stopped. The counting process makes it possible to achieve precise stacks even with thin printed products. However, the associated disadvantage is the restricted performance caused by the accumulating conveyor. In other words, after accumulating, the printed products cannot be accelerated fast enough even by using a suction belt. A further disadvantage is that the accumulating conveyor may leave pressure marks on printed products with sensitive surfaces.
DE3920557 C2 proposes regulating the number of cycles of the cutting device automatically as a function of the printed products fed to the stacking hopper of the cutting device per unit of time. Despite the irregular product flow, this is intended to permit substantially trouble-free operation of the cutting device. This method admittedly minimises the number of empty cycles, but cannot avoid them completely. The method is suited to cutting devices which are loaded at relatively low speeds. If products are supplied rapidly, jams may arise when loading is resumed after interrupting the product supply, because the cutting device has only a relatively low acceleration from standstill to production speed.
Using a loading device as shown in EP0887157 should make it possible to load a cutting device which guarantees a selection of different numbers of cut products even with a non-continuous and extremely rapid succession of supplied printed products. To this end, the loading device has a counting hopper with two stacking shelves positioned one on top of the other, these being automatically controlled by the supply and removal of printed products. A pusher positioned beneath the counting hopper enables complete stacks of printed products to be fed to the cutting section in synchronisation. The control system uses signals from sensors positioned on the hopper to detect book blocks, the first sensor being positioned directly in front of the hopper, the second sensor being located on the lower stacking shelves and the third sensor being positioned on the feed table. The counting hopper can be operated in different operating modes depending on the number of copies per stack.
DE10321370 also describes a cutting device with a counting hopper, a shingled stream separator being positioned upstream of this hopper. This should make it possible to reliably process thin products which are supplied in a shingled stream.
In an embodiment, the present invention provides a method for regulating a speed of a cutting device comprising a cutter for cutting printed products. The printed products are consecutively transported on a first conveying component of a feed device. A final printed product of a stack of the printed products to be formed is detected. The stack is formed in a stacking device. The stack is transported to the cutter using the feed device. An actual number of cycles of the cutter is regulated based on a time of the detecting the final printed product of the stack such that the stack is fed to the cutter within a time window.
The present invention will be described in even greater detail below based on the exemplary figures. The invention is not limited to the exemplary embodiments. All features described and/or illustrated herein can be used alone or combined in different combinations in embodiments of the invention. The features and advantages of various embodiments of the present invention will become apparent by reading the following detailed description with reference to the attached drawings which illustrate the following:
In an embodiment, the invention regulates the speed of a cutting device in such a way that the buffer capacity of the stacking hopper is always sufficient, even with an irregular supply of printed products, to avoid the hopper overfilling. In addition, the surfaces of the printed products are handled with care.
In an embodiment, the invention provides a method for regulating the speed of a cutting device in which the printed products in each stack to be formed are detected and an actual number of cycles of the cutter is regulated on the basis of the time of detecting a final printed product of each stack to be formed such that the stack is fed to the cutter within a time window.
The stack formed is preferably transported to the cutter on a second conveying component of the feed device. In this process, the time window is calculated as the difference between the longest time available and the shortest time available to feed the stack thus formed to the second conveying component.
In a preferred embodiment of the invention, the stack formed is transported to the cutter by means of a pusher on the second conveying component, a minimum and a maximum value for an offset time being calculated from the calculated time window and the stack being transported to the cutter on expiry of the offset time. The fact that the actual number of cycles of the cutter is calculated and adjusted accordingly makes it possible to ensure that the cutter is adjusted as continuously as possible to the speed of the supplied printed products.
In a preferred embodiment of the invention, the actual number of cycles of the cutter is regulated on the basis of the arrival time of the final printed product of a stack to be formed. In this process, the actual number of cycles of the cutter can be regulated by reducing or increasing this actual number of cycles compared with a previous number of cycles. If the final printed product of a stack to be formed is supplied very late, at least one empty cycle of the cutter is preferably inserted and the actual number of cycles of the cutter is increased.
In the preferred embodiment of the invention, the speed of the printed products on the first conveying component of the feed device is adjusted as a function of the length of the printed products and irrespective of the actual number of cycles of the cutter. In this process, printed products may be fed to the cutting device from a processing machine located upstream of the cutting device, a nominal number of cycles for the cutter of the cutting device being preset by the processing machine.
The conveying means 2 feeds the printed products 3 individually, one after the other, to a feed device 4 of the cutting device 1, which comprises an initial conveying component 26 designed as a conveyor belt in this case, which can be driven by means of an adjustable motor M1. The speed of the conveying means 2 located upstream of the first conveying component 26 is selected as a function of the length of the printed products 3 and the number of cycles of the processing machine 33 such that the gaps between consecutive printed products 3 on the conveying means 2 are as small as possible. The upper frequency of the supplied printed products 3 is thus limited. In order to ensure that gaps are formed between consecutive printed products 3 for visual detection purposes, for example, the speed of the first conveying component 26 is always higher than the speed of the conveying means 2.
The printed products 3 are fed to a stacking device 5 by means of the first conveying component 26, this stacking device being made up of a vertical stacking shaft 6 with upper stack pushers 7 and lower stack pushers 8 arranged on two levels. The stack pushers 7, 8 which are arranged in pairs can be moved in the direction of a double arrow D between a closed position, in which the printed products 3 are held back, and an open position, in which the printed products 3 are released. To avoid pressure marks on the lowermost printed product 3, the stack pushers 7, 8 are also accelerated vertically downwards when opening. The printed products 3 can be buffered for a certain time by the stacking device 5. The stacking shaft 6 is limited at its lower end by a second conveying component 9 in the form of a feed table onto which stacks 10 formed from a number of printed products 3 are fed from above by the stacking device 5.
The stacks 10 are conveyed on the second conveying component 9 by means of a pusher 11 which can also be moved forwards and backwards in the direction of the double arrow D to a cutting table of a cutter 12 of the cutting device 1. The stack 10 is then tensioned between the cutting table and a pressure plate. In this position, the stack 10 is cut at the front edge by means of a front blade 13 and at both side edges by means of side blades 14, although the cutting sequence can also be reversed. After releasing the pressure plate, the cut stack 10 is removed in a removal direction A by a first conveyor 15 and a subsequent second conveyor 16. The cutting table is then free to accept the next stack 10 to be cut.
The pusher 11 is preferably driven by a motor M2, front blade 13 and side blades 14 are driven jointly by a motor M3, the first conveyor 15 is driven by a motor M4 and the second conveyor 16 is driven by a motor M5. An additional motor M6 forms a main drive for the cutting device 1. The main drive drives all the components of the cutting device 1 not already mentioned, such as alignment components on the cutting table, transfer devices, etc., and forms the master drive for motors M1 . . . 5.
Motors M1 . . . 6 are designed as motors with rotational angle control which are connected to corresponding drive controllers A1 . . . 6. The drive controllers A1 . . . 6 are connected to a control device 17 to exchange control signals. Alternatively, the drive controllers A1 . . . 6 can be designed as part of the control device 17. Output terminals of the control device 17 are connected to actuating devices for the upper stack pushers 7 and the lower stack pushers 8 and input terminals of the control device 17 are connected to light barriers L1 . . . 3 and a sensor 24.
The light barrier L1 is located at the beginning and light barrier L3 is located at the end of the first conveying component 26. The light barrier L2 is located downstream of the light barrier L1, the distance 30 between these two light barriers L1, L2 corresponding to at least the length of a printed product 3 in the feed direction F.
The method is explained in detail below with reference to
The light beam of light barrier L2 is interrupted cyclically by the transported printed products 3. This results in a signal with dark phases 18 when the light beam is interrupted and light phases 19 when there are no printed products 3 in the vicinity of the light beam. A corresponding time diagram is shown at the top of
By incorporating the number of printed products 3 per stack 10 and the time between consecutive impulses 20, the control device 17 calculates an associated actual number of cycles TE or a machine cycle Zn of the cutting device 1 and drives the motor M6 by means of the drive controller A6 at the corresponding speed. With impulses 20 generated continuously by the L2 light barrier, this results in similarly continuous operation of the cutting device 1 with an actual number of cycles TE which corresponds to the nominal number of cycles TN. The actual upper number of cycles TE is limited by a maximum number of cycles TMAX and the lower number of cycles is limited by a minimum number of cycles TMIN.
The speed of the first conveying component 26 of the feed device 4 is calculated by the control device 17 on the basis of the length of the printed products 3 in the feed direction F, which is known to the control device 17, and the motor M1 is driven by the drive controller Al at the necessary speed, the lower speed of the first conveying component 26 being limited. On the one hand, this ensures that the gaps formed between the printed products 3 in the feed device 4 are large enough and, on the other hand, it ensures that the printed products 3 are fed (by dropping) into the stacking device 5 at not less than a minimum speed. A clock generator 22 is provided on a drive wheel 21 of the first conveying component 26, as shown in
By detecting the printed products 3 with the light barrier L2 and product tracking, the control device 17 is constantly able to calculate the position of a printed product 3 on the first conveying component 26 in relation to the light barrier L2 and a time tB required by a printed product 3 to cover a distance 31 between the light barrier L2 and the light barrier L3, or the time until the printed product 3 is due to arrive at the stacking shaft 6. The control device 17 can also calculate the minimum time required tk after the light barrier L3 detects a final printed product 3 of the stack to be formed for a finished stack 10 to be formed on the lower stack pushers 8 and a maximum time tl available before the lower stack pushers 8 must be opened so that they can be ready again in sufficient time to form the next stack 10. Within a time window 25 formed by time tl and time tk, the lower stack pushers 8 must be opened and the stack 10 thus fed from above onto the second conveying component 9.
On the other hand, the pusher 11 must be in a rear end position 27 when the lower stack pushers 8 are opened and may only commence its forward motion when the stack 10 is positioned on the second conveying component 9. The motion sequence 29 of the pusher 11 is illustrated in
The earliest possible time tf at which the pusher 11 can start to push is when the stack 10 is fed from above at time tk and reaches the second conveying component 9 directly after a dropping time to. The latest possible time ts at which the pusher 11 can start to push is when the stack 10 is fed from above at time tl, the pusher 11 has simultaneously reached its rear end position 27 and after the resting period tr during which the pusher 11 remains in the rear end position 27.
A range B, in which the pusher 11 can start to push a stack 10, can thus be calculated using the formula B=tl−tk+tr−to. Whenever the final printed product 3 in each stack 10 to be formed passes through the light barrier L2, the control device 17 calculates an offset time tOffset=tB+tk+to+tv until the start of the pushing motion of the pusher 11 (tv being a preferential time to be selected, see below) and adjusts the actual number of cycles TE or the machine cycle Zn of the cutter 12 such that the pushing motion can start precisely after the offset time tOffset. It is advantageous if the time tv is selected to be more or less equal to B/2 so as to be able to respond to both short-term increases or reductions in the feed speeds for printed products 3.
Whenever the final printed product 3 of a stack 10 to be formed passes through the light barrier L3, the control device 17 compares the calculated time tB with a measured time and adjusts the actual number of cycles TE of the cutter 12 in the event of any deviation such that the pushing motion is able to start at the intended point within range B. By measuring the arrival time of the printed products 3 at the stacking shaft 6, it is also possible to control the timing of the stack pushers 7, 8 more accurately.
The sequence is described using the stack 10, comprising three printed products 3 with numbers n1, n2, n3. Printed products 3 with numbers n1 and n2 are detected by the light barrier L2 and generate impulses 20 (n1) and 20 (n2). When the front edge of the printed product 3 with number n3 reaches the light barrier L2, times t1, tk, to, t, tr and tB are calculated. The control device 17 then uses these to calculate the offset time tOffset. Some of the values for times tl, t tk, to, tv, tr and tB can alternatively be stored as constants in a memory of the control device 17 and read out from here. The value for to may, for example, be classified as a constant if the dropping time to for a stack 10 always has the same value in the same stacking device 5 due to design constraints.
If the calculation reveals that, when the cutter 12 of the cutting device 1 is once again operating with the current actual number of cycles TE, after expiry of time tOffset, the pusher 11 can start pushing, the actual number of cycles TE remains constant. Otherwise, the actual number of cycles TE is adjusted as explained in further detail in the rest of the description.
The method, in an embodiment, can be described in simple terms as a synchronisation method for the cutter 12 of a cutting device 1 by prior detection of printed products 3 and regulation of the actual number of cycles of the cutter 12 according to the supplied printed products 3, in which the actual number of cycles TE of the cutter 12 is increased if the stack 10 to be cut is formed too late and at least one empty cycle is generated. The control device 17 is able to establish whether a printed product 3 is on the first conveying component 26, and precisely where on the component it is, by means of the light barriers L1 and L2 together with the clock generator 22. This enables the first conveying component 26 to be run empty at the original speed or stopped sufficiently quickly so that a printed product 3 is not fed to the stacking device 5 at an excessively low speed in the event of the cutting device 1 and/or the conveying means 2 stopping. If there is still a printed product 3 on the first conveying component 26 after the first conveying component 26 has stopped, the first conveying component 26 is driven backwards until the printed product 3 is detected by the light barrier L1.
After the first conveying component 26 restarts in the feed direction F, the printed product 3 located on the conveying component then has a long acceleration time so that it can be fed (by dropping) to the stacking device 5 at full speed.
While the invention has been illustrated and described in detail in the drawings and foregoing description, such illustration and description are to be considered illustrative or exemplary and not restrictive. It will be understood that changes and modifications may be made by those of ordinary skill within the scope of the following claims. In particular, the present invention covers further embodiments with any combination of features from different embodiments described above and below.
Number | Date | Country | Kind |
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01338/11 | Aug 2011 | CH | national |