DE2458415A1 - METHOD AND DEVICE FOR CONTROLLING THE QUANTITY OF A SINGLE-LAYERED MATERIAL WITHIN A STORAGE AREA FLOWS FROM A TREATMENT STATION PROCESSING THE SINGLE-LAYERED MATERIAL TO A DOUBLE-LAYERED MATERIAL - Google Patents

Description

PATENT ADVOCATES A. GRÜNECKER

DiPL.-ING

H. KINKELDEY

DR-ING

W. STOCKMAIR

DtI-ING- ΛοΕ (CALTECI P

2458 A 15- K.SCHUMANN

_m Since RER. NAT. - Often.-PHYS.

P. H. JAKOB

UPU-ING

G. BEZOLD

DfI RfA ΝΛΤ ■ DiPL C (FM.

MUNICH

E. K. WEIL

DR RER CEC INt ₁

8 MUNICH 22

MAXIMILIANSTRASSE 43

December 9, 1974 'P 8790 -52 / Hä

LINDAU

Copar Corporation
5744 West 77th Street,

Oak Lawn, Illinois 60459, USA

Method and apparatus for controlling the amount of a single layer material within a storage area upstream of the single layer material to a double layer Material processing treatment center

The invention relates to a method and apparatus for controlling the amount of a single-layer material within a storage area upstream of a treatment site converting the single-layer material into a double-layer material. With the help of this method and the device, the amount of the single-layer material present in the storage area or a so-called bridge is to be kept at a certain size, the single-layer material being withdrawn from this amount present in the storage area in order to produce the double-layer material intended further material to be processed in the treatment center. 509835/0261

TELEPHONE (089) 22 29 62 TELEX 00-29 380 TELEGRAMS ΜΟΝΛΡΑΤ

The object of the invention is to provide a method and a device indicate with which in a simple manner the amount of material of the single-layer material in the storage area can be kept within a certain range to avoid warping of the single-layer material in the To prevent storage area due to an excessively large amount, on the other hand, however, a sufficient supply at all times of single-layer material for delivery to the treatment site to be ready. '

In a method of the type mentioned, this object is achieved according to the invention in that the speed of the drive for the single-layer material and that of the material provided for double-layer formation and for Formation of a signal proportional to the speed difference is compared that the amount of the in the Storage area moving in and that of the single-layer material leaving it detected and the difference in quantity proportional signal is generated and that the speed proportional and the amount proportional Signal to control the speed of the drive for the single-layer material is used.

According to a development of the invention, a device created to carry out this method, which is characterized according to the invention by a first device for Detection of the speed of the drive for the single shift Material and a second device for detecting the speed of the drive for the double layer formation provided material and a third device for comparing these speeds and generating one of them Difference proportional output signal, by a first pulse generator to detect the amount of energy in the Storage area of single-layer material moving in

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and a second pulse generator for detecting the amount of the single-layer material leaving the storage area and a comparator connected to the pulse generators to generate an output signal proportional to the quantity difference and by speed control means for driving the single layer material to which the are fed to both output signals.

According to further developments of the invention specified in the further claims, the speed of the area of material moving in, which is next to the Inlet of the storage area is measured, compared with the speed of the material leaving the storage area measured next to the outlet of the storage area. The comparison result becomes a maintenance in turn a certain amount of material used within the storage area. It can actually do this The amount of material present in the storage area can be detected. According to another feature it becomes a moistened Area of the single-layer material to determine the amount of the material used within the storage area.

Corrugated cardboard is often used in the manufacture of cardboard boxes used, which is made from three sheets of paper. the two outer sheets are called the cover sheets and the corrugated middle sheet is called the intermediate layer.

In the manufacture of the corrugated board, the corrugated center sheet is formed by running paper through corrugated rollers made, after which glue is applied to the vertices of the corrugated paper and a cover sheet with a Side of the corrugated interleaf is joined. This combination a top sheet and the corrugated interleaf is referred to in the industry as a single layer material.

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So that the adhesive can dry and harden, the single-layer Material that is still flexible in the conveying direction of the machine onto a slowly moving one Dropped tape that acts as a storage area and is also known as a bridge. The material is from the Bridge removed by a handling facility in which Adhesive to the free vertices of the corrugated interlayer. material is fed and a second cover sheet with the single-layer Material is combined to produce the well-known corrugated cardboard, which is then also called double-layered Material is to be designated. After both cover sheets have been applied, the material passes through one of one Dryer and a pull roller existing facility through and from there on knives that cut the material into lengths suitable for cardboard manufacture. To that Avoid stopping the entire machine when either a cover sheet or a middle sheet collection is spliced in again the double-layer area and the single-layer area Area of independent drives. The speed of the intended for bilayer formation Material is operated by an operator at the cutting end of the machine and the drive for the single-layer material is controlled by an operator responsible for this. The bridge described above forms the memory area between the drive for the single-layer material and the drive for that provided for the double-layer formation Material.

The speed for the material intended for bilayer formation is determined by the removal of the cut leaves and their quality control controlled. The speed of the single layer material is of the associated operator controlled so that a desired amount of single-layer material is in the Bridge is located. The speed of the bridge forming

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Volume can range from a third to a fifteenth of that Vary the speed of the single layer material. Will be the speed of the double layer formation If the intended material is made faster than the speed for the single-layer material, this will be in the Bridge-stored, lobed material decreased in length while reducing speed of the material intended for the formation of the double layer is below that of the single-layer material lobed material will accumulate within the bridge. In this way the operator thinks for the single shift Material the desired number of meters within the bridge to prevent the material from tearing when the speed changes of the material intended for the formation of the double layer.

Up until now it was common for the operator to work for the one-shift Material has loaded lobed material into the bridge to its maximum capacity. This results in however, there is the disadvantage that uneven drying and warping can occur in the finished corrugated board.

One of the most important purposes, the speed of the single shift Material and that of the double layer provided material is independent of each other and to maintain a changing supply in the bridge that when one of the feed rollers for the one cover sheet or the corrugated interleaf sheet runs out, the operator for the single-layer material its speed over that of the material intended for the double-layer formation met, and thus stores a good 100 m of the single-layer material in the bridge, after which he -the machine is sufficient slow down, in order to be able to splice in a new roll without the single-layer material within the Bridge goes out, and thus the material intended for the formation of the double layer would have to be stopped in order to remove the

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-S-

To wait for splicing. During this time, however, a too large a quantity of single-layer material in the bridge can be accepted, although this causes certain distortions in the end product.

It has been found that faults become as small as possible with a minimal amount of material in the bridge is held, - so that the single-layer material is essentially is produced at the same speed as it is bonded to the further material to form the double layer will. With an increase or decrease in the speed of the material intended for double layer formation this should therefore be adapted to an increase or decrease in the speed of the single-layer material, and thus an approximately constant length of material can be maintained in the bridge.

The most recent tests have shown that a minimum warpage of about 7-5 to 15 ι straight length of smooth material should be kept in the bridge. Since the machine usually runs at a speed of 120 to 150 m / min works at a speed difference of about 3 m a length of 7 ^ m of stored material only one Drift of 2.5 min. As the problem of maintaining this amount of material in the bridge at these speeds The new method makes too great demands on an operator for the single-layer material and the device provides an automatic speed control for the single layer material to thereby automatically maintain a predetermined amount of material within the bridge. In addition, the Control adding a certain amount of. Material into the bridge to prevent splicing when a wrapper or to prepare an interleaf roll and then the

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The bridge material can be traced back to the specified amount after the end of the splicing process. Also enables the control switches on a valve for an automatic water spray device during the splicing time, to prevent the single layer material from drying out if the speed of the single-layer material sinks below that of the material intended for double-layer formation.

The invention is explained in more detail using an exemplary embodiment shown in the drawing. Show in detail:

1 shows a schematic representation of part of a machine for producing corrugated cardboard,

Fig. 2 is a block diagram of the new control device, and

3 shows a modified control device, partly in form a block diagram.

In Fig. 1, a roller 10 guides the intermediate sheet 12 over spaced apart sheets Rollers 14 and 16 to corrugated rollers 18, on which the interleaf is curled, after which it is on roller 21 is assembled with a cover sheet 20 to form the single layer material. This cover sheet is used by the Roll 22 is fed over rolls 24 and 26 before it "enters the assembly roll." 21 reached. The feed rollers for the adhesive are omitted because they do not play a role here. After joining the selected intermediate sheet and the one cover sheet 20 for the single-layer material This arrives upwards via a roller 28 and a roller 30 to a point where the single-layer material hits a moving belt 32 is lowered. The band 32 forms the bridge or the storage area and that

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Material is deposited on the belt 32 at the speed of the single layer material. One roll 34 for one another cover sheet 36, with which the double-layer material is produced, arrives via spaced rollers 38 and 40 to a point 42 where this further cover sheet 36 is connected to the single-layer material 44. Here, too, the rollers that feed the adhesive are omitted. The single layer material 44 passes over rollers 46 and 48 after it is removed from the right end of the bridge 32 became.

In addition to the role 24, over which the formation of the single-layer Material provided cover sheet 20 is conveyed, a pulse generator 50 is provided, which a certain number of pulses per length of the cover sheet, e.g. 3 pulses generated per meter. Similar is a pulse generator 52 next to the roll 38 for the further cover sheet, which generates a certain number of pulses per length of the additional cover sheet, e.g. 3 pulses per meter

A first measuring wheel 54 is arranged near the inlet of the bridge 32, to determine the speed of the material moving through the bridge at this point. That Measuring wheel 5 ^ thus measures the speed of the itself over it moving material when it is carried by the belt 32. A second measuring wheel 56 is provided on the bridge 32, which is arranged a certain distance from the measuring wheel 54 and measures the speed of the material on the bridge at that point. Therefore, the belt 32 runs with a certain Speed versus speed for the single-layer material fed, e.g. one seventh of this speed, and the measuring wheel measures a movement of the material at 1/7 the speed of the single layer Material, the measuring wheel 54 measures the movement

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■ Si lobed material. On the other hand, if the measuring wheel 56 measures movement of the material at the same speed as that of the single layer material or that of the double layer material, then obviously there is no longer any lobed material on the bridge at that point.

In IPig. 2 shows a pair of tachometers 58 and 60, wherein the tachometer 58 the speed of the drive of the single layer material and the tachometer 60 measures the speed of the drive of the double layer material. The outputs of the two tachometers 58 and 60 are respectively Connected to the input of an operational amplifier 66 via potentiometers 62 and 64. In this way they are. Input signals to amplifier 66 from the tachometers Voltage whose polarity and amplitude differ according to the difference between the speed of the single layer and that of the double layer material changes. If the drive speeds are identical or equal to one another, so there is no input voltage to the op amp 66 arrive. .

The pulse generators 50 and 52 are each provided with a Synchronization gate 68 connected, the output of which is connected to a four-decade up-down counter 70 is. As previously stated, each of the pulse generators are there 50 and 52 a certain number of output pulses per Meters of material running over the generators. The synchronization gate 68 only ensures that pulses are also given to the counter when the The pulses from the two pulse generators coincide. Of the Counter 70 is connected to a digital-to-analog converter 72, the output of which is connected to the operational amplifier 66.

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During operation, the impulses of the one impulse generator cause an upward counting, while the pulses of the other pulse generator cause a downward counting, so that the counter 70 will have a count of zero when the same amount of material is passed through each pulse generator is moved. A negative or positive count at the output of counter 70 causes a negative one or positive voltage at the output of transducer 72 to increase the speed of the drive for the single shift Change material.

The output of op amp 66 is five different Schmitt triggers 74-76,78,80 and 82 connected. The output of the Schmitt trigger 74- is with an OR gate 84, the output of which is connected to a relay winding 88 via a driver amplifier 86. The exit the Schmitt trigger 76 is connected to an AND gate 90, the output of which is connected to the OR gate 84. A timer 92 is with AND gate 90 and with one AND gate 94 connected, which is an input signal from the Schmitt trigger 78 receives. The output of the AND gate 94 is connected to an OR gate 96, which is also an input signal received from Schmitt trigger 80. The output of the OR gate 96 is via a driver amplifier 98 with a Relay winding 100 connected. The Schmitt trigger 82 is directly connected to a driver amplifier 102 with a Relay winding 104 connected.

The speed of the drive motor for the single-layer material is set with the aid of a motor-driven potentiometer set. The operator usually operates this potentiometer by pressing either an accelerator or delay button. The relay windings

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88 and 100 control contacts that connect these buttons in parallel so that one goes through any of these windings flowing current causes the motor-driven potentiometer the speed of the drive motor for the single-layer material increases or decreases.

Assume an operating condition in which the speed of the single-layer material and that of the double-layer material Materials are equal to each other, there is no difference between the output signals of the Speedometer 58 and 60 and therefore no input signal for the operational amplifier 66. If we also assume that the movement of material is the same, it results also no input signal from the counter 70 and the digital-to-analog converter 72 for the operational amplifier 66, see above so that neither of the windings 88 or 100 changes the speed of the drive motor for the single layer material. However, if the single-layer material is moved at a greater speed than the double-layered material Material, a signal proportional to this results for the amplifier 66 and assumed, the output voltage of "amplifier 66 is above a certain level, E.g. 2.5 volts, this is how the voltage-sensitive Schmitt trigger generates. 74 a signal via the OR gate 84 so that the Relay winding 88 responds in order to continuously the Operate motorized potentiometers to change the speed of the single layer of material. Is the If the voltage difference at the output of the amplifier 66 is less than 2.5 volts, but above 0.25 volts, the Schmitt trigger gives 66 an output signal to the two AND gates and 94. Every time the timer 92 has an output signal generates what takes place in a certain time sequence, so the AND gate 90 gives an output signal

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to the OR gate 84, whereby, a current through the winding flows during a certain period of time which coincides with the time sequence of the timer 92. ! So step on If there is a smaller difference between the two speeds, the motor-driven potentiometer will only be long-sam or piece by piece the drive for the single-layer material control until the two speeds match again.

If the speed difference is reversed, e.g. the speed of the single-layer material is lower than that of the double-layer material, the Schmitt triggers 78 and 80 reverse the direction of the motor-driven one Potentiometer that controls the speed for the single-layer material in the manner described.

Both the tachometers 58 and 60 and the pulse generators 50 and 52 both generate information about the differences the movement between the single-layer material and the double-layer material. However, since the tachometers do not linear output voltage over the entire speed range, must be able to produce their information with those of the pulse generators are combined, which with the aid of the summing counter 70 a correction for an enlargement or lose material due to tachometer errors.

If the entire system is put into operation, the operator sets the speed for the single shift Hand in material until the desired amount of single layer material is in the bridge. then the operator presses a button on the overall control which resets the counter 70 to zero. After that works the control device so that the speed of the drive

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for the single-layer material in the required manner is set to the "certain amount of single-layer Maintain material in the bridge.

As stated above, the single-layer material must be accelerated from time to time in order to obtain a sufficient amount of material in the Ensure bridge for the splicing time. A splice preparation switch 106 is connected to a bistable circuit 108. A splice end switch 110 comes with a second bistable circuit 112 connected. The bistable circuits 108 and 112 have a rotary potentiometer 114 connected for a splice supply, which in turn is connected to the output of the digital-to-analog converter 72 is. A two-decade counter 116 for the splice supply is connected to the output of the bistable circuit 108 and emits an input signal for the counter 70.

Should a new roll of the first cover sheet or the interleaf are spliced in, the splice preparation switch 106 is closed, whereby both bistable Circuits 108 and 112 change their switching state. When changing the switching state of the bistable circuit 112 this outputs a blocking signal via the line 118 to the digital-to-analog converter 72. At the same time, an alternating signal is transmitted the line 115 is given to the operational amplifier 66, the supplied voltage being controlled by the setting potentiometer 114 is intended for the splicing stock. In this way, the drive for the single-layer material has a larger one Speed up a certain amount of material is stored in the bridge, due to the coincidence between the counter 116 and the counter 70 is given. At this time the desired additional material is located in the bridge and the motor for driving the single-shift Material is reduced to a speed that

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that of the double-layer material is adapted. To do the splicing, the operator slows down the drive for the single-layer material. After completing the splicing, the operator operates the switch 110, which returns the bistable circuits to their original switching state, so that the control device is now working in its normal way again.

During the splicing process, it may be desirable to operate a water spray device so that the material can be removed does not get too dry inside the bridge.

There is a direct connection between the bistable circuit 108 and the Schmitt trigger 82 via the line 120. So if this particular mode of operation is to be possible, then so is during the splicing process with the splicing switch closed 106 emitted a signal from the Schmitt trigger 82 via the driver amplifier 102 to the relay winding 104, which causes the single-layer material to be sprayed with water during the splicing process.

The measuring wheels 54 and 56, which measure the amount of material in the Bridge next to its inlet and measure at a certain distance from it are each with a synchronization gate 122 connected, which enables a determination of the impulses even if they coincide and in turn with a two-decade up-down counter 124 is connected is. The counter 124- is connected to the output via a bistable circuit 126 and a circuit 128 dividing by a hundred of the pulse generator 52 connected.

The output of the counter 124 is connected to a tolerance gate 130 connected, which in turn is connected to AND gates 132 and 134 is. AND gates 132 and 134 also receive

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Inputs from counter 124. AND gates 132 and are connected to a one-decade counter 136 which has Outputs connected to the counter 70 on lines 138 and 140 and these lines are also connected to an OR gate 142. The output of OR gate 142 is connected to the counter 70, with an additional output of the counter 136 via line 144 also with the Counter 70 is connected. The circuit is completed by a two-decade counter 146 for a correction of the The number of meters of material in the bridge.

As previously mentioned, the speed of the belt 32 in the bridge is much slower than that of the single or double layer material. Assuming <3ώ the speed of the belt is 1/7 of that of the single-layer material, the excess material or lobed material on the bridge is stored in the order of about 7 m of material per 1 m bridge length. If the measuring wheel 54 is to measure lobed material and the measuring wheel 56 is to measure the material moving at the speed of the double-layered material, the measuring wheel 56 moves at seven times the speed of the measuring wheel 54. On the other hand, if both measuring wheels are covered with lobed material or none of them If the measuring wheels are covered by lapped material, both measuring wheels move at the same speed. If it is assumed that the measuring wheels 54 and 56 each have a circumference of about 0.6 m and each generates 10 pulses per revolution, each measuring wheel emits seven pulses or a total of fourteen pulses when both measuring wheels are driven by lobed material. If the measuring wheel 54 is covered by lapped material, but the measuring wheel 56 is only covered with material that is moved at the speed of the double-layered material, the measuring

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wheel 54 seven pulses and the measuring wheel 56 fifty pulses or both together fifty-seven pulses. On the other hand, it is not the measuring wheels are covered by lobed material, but each is moving at the speed of the single-layer or double-layer Driven material, the two measuring wheels together generate 100 pulses ".

Since the measuring wheel 54 with lobed material and the measuring wheel 56 be covered with single-layer material moving at the speed of the double-layer material the counter 124 is preset to 57 counts. If material is stored in the bridge in the desired way, so the measuring wheels 54 and 56 reduce the count to zero within an acquisition or sampling interval. The sampling interval in this context becomes through the divider circuit 128 and the bistable circuit 126, which provides a sampling or acquisition interval every approximately 6 m from the material leaving the bridge is. The bistable circuit 126 controls the count and the display interval of the counter 124. The counter 124 therefore detects information from the measuring wheels 54 and 56 via synchronization gate 122 during an interval corresponding to approximately three meters from material exiting the bridge and displays during an interval that also corresponds to about 3 ni of material exiting the bridge. The counter 124 is automatically reset to -57 at the end of the display period. If there is an operating state before, as it was described, and is the measuring wheel 54-of smooth material and the measuring wheel 56 is not covered by smooth material, the stored in counter 124 is Count of 57 within the sampling interval to zero counted. If, on the other hand, both measuring wheels are covered by lobed material or neither of the measuring wheels is lobed Material covered or are during a part

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the counting period covers both measuring wheels or none of the measuring wheels by lapped material, the counter reading is not reduced from 57 to zero. If the count of both measuring wheels 57 exceeds _5, the counter first counts to zero and then continues upwards. This requires the use of a single preset.

In the example given, the maximum counting error is 43 in both the plus and minus directions, depending on whether lobed material is on both measuring wheels or there is no lobed material on both measuring wheels. The tolerance gate ' 130 determines the respective tolerance of the arrangement in view of excess material or less Material within the bridge can still be tolerated in order to have satisfactory operating conditions. Is that for example Tolerance gate set to 20 counts in both plus and minus directions, so every time the tolerance setting is exceeded, an output signal is given to AND gates 132 or 134, depending on whether the exceedance occurs in the plus or minus direction. This causes an output from counter 124 to each of the AND gates and an output signal from the tolerance gate 130 an output from each of the AND gates I32 or 134- to counter 136 * depending on whether the remaining one Count re-stand has a plus or minus sign. After three successive input signals to the counter 136 which are caused by an excess retained count in counter 124 · in the same direction are, an output from the counter I36 is sent to the counter 70 in either plus or minus direction and an immediate Output signal to open the counter 70 given so that a certain count from the two-decade switch 146 can be entered. Can therefore have a tolerance of

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20 counts can still be coped with as operational errors} this tolerance becomes in three consecutive sampling intervals exceeded, however, after the third interval a counter reading equal to the tolerance, i.e. 20, automatically entered into the counter 70 using the switch 146, which is controlled by the counter 136 and the OR, Member 142 is controlled. This entering of a predetermined counter reading either in plus or minus direction ' in the counter automatically causes a correction voltage in the correct direction, which is applied to the input of the amplifier 66 is given, whereby the drive motor for the single-layer material is controlled in the correct direction is used to bring the amount of lobed material in the bridge to the specified value. In this way, the Entering a positive count of 20, that automatically the drive motor of the single-layer material in 'a is controlled in such a direction as to remove the excess material in the bridge, i.e. the drive motor for the single layer material is slowed down. Has a stable state been restored, i.e. is located If the appropriate amount of material is in the bridge, which is detected by the measuring wheels 54 and 56, then the The drive motor for the single-layer material is automatically returned to its normal speed.

This "compensation arrangement described above is desirable because over long periods of operation there is a tendency that material in the bridge as a result of small measurement errors and from dimensional changes of the material accumulates or is lost in the bridge. The compensation arrangement corrects these errors caused by measuring wheels 54 and 56 are detected, periodically.

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As an accurate means of determining how much material is in the bridge for a 'given time, this device' acting as a further compensation control can be used for the drive motor of the single-layer material, a counter 150 shown in FIG always reset to bull when a "valve 152 for a water spray device is opened to put water on. spray a specific area of the single layer material. This spray device is provided on the roller 30. The counter 150 adds up counts until it reaches from a detector 154- next to the bridge outlet is stopped. The detector 154-, which is placed on the roller 46, can consist of two electrically isolated wheels arranged side by side and connected to a resistance measuring circuit which detect a moistened patch of the single layer material. Because the entire length of the bridge is accurate is known and since the coverage of the moistened spot indicates the total amount of material within the bridge gives the difference is the excess lobed material, which is an indication of the total stored in the bridge Amount of material is.

Although the invention is explained on the basis of exemplary embodiments it is of course not limited to the details of these / exemplary embodiments, but can rather, all of the description, the drawing, and the claims removable features can be essential to the invention both on their own and in any combination.

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Claims (1)

Claims 1.) Method of controlling the amount of a single layer ifaterials within a storage area upstream of a the single-layer material to a double-layer material processing treatment site, characterized in that the speed of the Drive for the single-layer material and that of the material provided for double-layer formation is detected and to form a signal proportional to the speed difference is compared that the amount of in the storage area moving in and that of the single-layer material leaving it detected and the difference in quantity proportional signal is generated, and that the speed proportional and that of the amount proportional signal is used to control the speed of the drive for the single-layer material. 2. The method according to claim 1, characterized in that that the speed of the single layer Material adjacent to the inlet of the storage area and adjacent to the outlet of the storage area is measured that these speeds are compared and that the resulting comparison result to maintain a certain Amount of material used within the storage area will. J. The method according to claim 2, characterized in that the comparison result with a A certain level is supplied and that the drive for the single-layer material is always set when the 509835/0261 certain level is exceeded a certain number of times. M-. A method according to any one of claims Λ in to 3> characterized in that the amount of the material is measured within the storage area periodically. 5. The method according to claim 4, characterized in that this periodic measurement Liquid is added to the single layer material as it enters the storage area and that subsequently the humidified area is detected. 6. Apparatus for controlling the amount of single layer material within a storage area upstream of a A treatment site converting the single-layer material into a double-layer material, characterized by a first device (58) for Detection of the speed of the drive for the single shift Material (20) and a second device (60) for detecting the speed of the drive for the Double layer formation provided material (36), as well as one third means (62,64) for comparing these speeds and generating one proportional to their difference Output signal, by a first pulse generator (50) for detecting the amount of the in the memory area (32) moving in single-layer material and a second pulse generator (52) for detecting the amount of single-layer material leaving the storage area, as well as a comparator connected to the pulse generators (70) for generating an output signal proportional to the quantity difference and by a speed control device (66,88,100) for driving the single shift 509835/0261 Material to which the two output signals are fed. 7. Apparatus according to claim 6, characterized in that the comparator (70) has a counter which the first pulse generator (50) .aufwärts ^ and the second pulse generator (52) counts down. 8. Apparatus according to claim 7 _5, characterized in that a digital-to-analog converter (72) is connected to the counter (70), the output of which is connected to the speed control device (66,88,100). 9. Apparatus according to claim 8, characterized in that the speed control device (66,88,100) has an operational amplifier (66) to which the digital-to-analog converter (72) is connected and supplies it with an input signal. 10. Apparatus according to claim 9, characterized in that the first and second devices (58,60) have tachometers, each of which is connected to the operational amplifier (66). 11. Device according to one of claims 6 to 10, characterized by a third device for detecting the speed of the material moving next to the inlet of the storage area (32) and by fourth means (56) for detecting the speed of the adjacent to the outlet of the storage area moving material, and a fifth means (124) for comparing the two of the third 509835/0261 and fourth means sensed speeds and by a sixth device (132,134,136) for feeding this Comparison result to the comparator (70). 12. Device according to. Claim 11, characterized in that the sixth device (132, 134, 136) and the comparator (170) a tolerance device (130) is connected, the sixth device only then forwards the comparison result to the fifth device (I24) if the comparison result has a preset value the tolerance device exceeds. 13. Device according to. Claim 11 or 12, characterized in that the fifth device (124) has a counter and that the tolerance device designed as a tolerance gate (130) is connected to this counter, which is also connected to the sixth facility (132,134,136) is. 14. The device according to claim 13, characterized in that the sixth device (132,134,136) a pulse emitting device (136) connected to the comparator (70) and from the tolerance gate (130) is controlled. 15. The device according to 'claim 14, characterized in that the pulse generating device (136) is programmed so that it outputs the same specific counter reading to the comparator (70) that also, as Threshold counter reading is set in the tolerance gate. 509835/0261 .24- 16. Device according to one of claims 6 to 15 _}, characterized in that a further counter (150) is provided for detecting the amount of material flowing into the storage areas (32) during a predetermined period of time. 17 »The device according to claim 16, since it shows that it is that seventh means (152) for supplying liquid to a portion of the single layer Material as it enters the storage area (32) and an eighth means (154-) for detection of the location of the humidified area adjacent to the outlet of the storage area. 18. Apparatus according to claim 17 »characterized in that a ninth device for Start the further counter (152) when the liquid is supplied to the single-layer material and a tenth Means for stopping the counter when detecting the moistened material are provided. 19. Device according to one of claims 6 to 18, characterized marked that an eleventh facility (106,108,110,112) is provided for deactivating the comparator (70) during a predetermined period of time. 509835/0261 Blank page