DE3206272C2 - - Google Patents

Description

The invention relates to a method and an apparatus for successive manufacture of coils of thread existing trees, according to the preambles of claims 1 and 2.

Accordingly, a thread wrap is always constructed in the form of a band. It educates on its winding body a spiral winding, which also to the side can be distorted, as is the case with successive Archiving several warping belts on a common warping drum the case is. Mostly it will be the trees Act partial warp beams that run together after winding should.

In the event that several thread groups or several trees submitted to an unwinder together, it is Desires that the same length of thread on all thread packages is available. Are these Winding devices where the winding body is not free are rotatable, but are inevitably driven and consequently, it must also run at the same speed, it is sufficient not if only the length of the wound goods for everyone running winding body is the same. So in the same Periods of equal length of the good of all Winding bodies can be unwound, should also be to the respective thread length belonging to the winding diameter of the individual Winding form be the same. Only then are the thread tensions at  Roughly unwind at every stage of the unwind process to keep at the same value.

DE-OS 17 74 229 a winding device for thread or band-shaped material known with a device for Generation of the number of revolutions of the winding body proportional values and a device for generating the Length of the wound material is provided with proportional values. Both devices are such with a storage device connected that for each a predetermined number of Revolutions the associated values of the lengths of the wound Good things can be saved or vice versa. The storage device is with one the tension of the goods and / or the pressing of the winding influencing in a subsequent winding process Control device can be coupled.

To control a differential gear is required, the of a pair of wheels depending on the stored values of the Storage device is driven and its rocker with the Adjusting element of the thread tensioning device and / or one Winding press device is connected. Especially if that Differential gear to actuate the winding press device, such a transmission is relatively expensive. To the It would be making the first wrap serving as a pattern wrap required to block the differential gear. At the Manufacture of the other wraps consists of their Wrapping condition no longer an overview. Error of intended control or regulation of the subsequent windings remain undetected.

CH-PS 3 76 068 is a method and an apparatus to determine the effective on a winder wound length of a winding known. The bobbin is connected to the adder that counts the revolutions. A own the wrapping material  The constant for the order is in stepping switches adjustable stride length and the excess length Adding unit also fed. Both values are in the adder added and reproduced digitally. When you reach one adjustable, effectively wound length is the Winding device stopped. The purpose of these measures is Obtain bobbins of the same winding length.

DE-OS 25 12 213 is a method and an apparatus to keep the gear ratio of rotating Machine parts of a textile machine known. The speeds Both machine parts are digital in the form of pulse trains captured and subtracted from each other. The difference is called Control deviation entered a transformer that the Control deviation converted into a manipulated variable that one Actuator is supplied that the drive device one of the controls two machine parts, the pulse processing is preferably carried out electronically.

From DE-OS 27 32 420 is an electronically controlled Winding unit known that the melt spinning from a Melt freshly spun threads at a very high speed withdraws from the spinneret and winds up. The known method is based on the task, the winding tension during the entire winding process within the narrowest possible limits to keep. To do this, it is necessary that in their basic tendency constant peripheral speed of the take-up reel modify. This happens because the Circumferential speed of the winding, with the winding getting thicker is increased to a lesser extent than the ratio of the  current winding diameter to the diameter of the bobbin tube would correspond.

With the help of the known devices and the known It is not possible to ensure that the Thread winding in the winding structure with regard to thread length and in the the winding diameter belonging to the respective thread length to match.

The invention is based, during the successive task Finishing the trees deviations in the winding condition of the tree in progress from a given one Continuous determination of the winding condition, display and for to use a correction of the wrapping condition that always a thread wrap through  the entire winding structure with regard to thread length and the respective Thread length belonging to the winding diameter of each of the remaining Thread wrap is the same. This object is achieved by the in claim 1 described invention solved. To perform the new one The method is the new device described in claim 2 suggested. Further embodiments of the invention are in the Subclaims described.

The advantages achieved with the invention are in particular in the fact that the above-mentioned unwinding operations conditions are always the same and therefore unnecessary Thread breaks are avoided, the number of thread connection points is reduced and overall in the processing stages a higher quality level can be assumed.

Based on the embodiment shown in the drawing the invention is to be further explained and described.

The drawing schematically shows a winding device 1 , the tree 2 of which is connected to an engine 3 which has a speed-determining device 4 . The engine 3 can be, for example, an electric motor and the speed-determining device 4 can be a controllable electric current gate.

A group of threads 6 is fed from a gate 5 to the tree 2 via a measuring roller 7 . The measuring roller 7 is wrapped over part of its circumference by the thread sheet 6 and driven by the thread sheet 6 . The gate 5 has thread brakes, not shown, which has a common braking force control device 8 .

During the winding process, a winding forms on the tree 2 , which is constantly pressed by a pressure roller 9 . The pressure roller 9 does not have its own drive, but is rotated in that it rests on the winding. However, it has two controllable pressing devices 10 and 11 which determine the respective contact pressure.

The tree 2 is connected to a first pulse generator 12 , which generates pulses that are proportional to the revolutions of the tree 2 . The measuring roller 7 is connected to a second pulse generator 13 which generates pulses which are proportional to the revolutions of the measuring roller 7 and thus also to the thread length running up.

The pulse generator 12 is connected to a multiplier 16 by an active connection 14 . The pulse generator 13 is connected to the same multiplier 16 by an operative connection 15 . The multiplier 16 has a line connection 17 to a comparator 19 . Multiplier 16 and comparator 19 can be alternately connected to a memory 21 via a changeover switch 20 , specifically the multiplier 16 can be connected to the input 24 via a contact 22 and the comparator 19 can be connected to the output 25 of the memory 21 via a contact 23 . The memory 21 also has an erase input 26 .

A revolution counter 27 is connected to the pulse generator 12 . It can have several free inputs 29 , 30 for entering limit data. In addition, the revolution counter 27 has an erase input 31 . A thread length counter 28 is connected to the pulse counter 13 . The thread length counter 28 has a free input 32 and a clear input 33 . The two counters can therefore be deleted and then start counting again. A thread speed meter 34 is also connected to the pulse counter 13 . The thread speed meter 34 is calibrated in meters per minute.

A line connection 35 leads from the comparator 19 , a line connection 36 leads from the revolution counter 27 , a line connection 37 leads from the thread length counter 28 and a line connection 38 leads from the thread speed meter 34 to a changeover switch 39 .

The changeover contact 40 of the changeover switch 39 is connected to a display device 42 by a line 41 .

The measuring roller is connected to a generator 43 which generates an electrical voltage which is proportional to the speed of the measuring roller 7 and which is input via a line 44 into the speed-determining device 4 .

A branch 41 'of line 41 leads to a control device 45 . An active connection 46 leads from the control device 45 to the braking force control device 8 , an active connection 47 to the speed-determining device 4 and an active connection 48 to the two pressure devices 10 and 11 .

Proceed as follows to manufacture the first roll:

The two counters 27 and 28 are set to zero via the clear inputs 31 and 33 . The contact 22 of the switch 20 is turned on. The memory 21 is set to zero via the erase input 26 . After the thread sheet 6 has been placed on the tree 2 , the engine 3 is now put into operation and the winding is started. The revolutions of the tree 2 are counted by the pulse counter 12 in the form of pulses, from which the revolution counter 27 determines the number of revolutions. At the same time, the accumulating thread length is counted in the form of pulses by the pulse counter 13 , from which the thread length counter 28 determines the accumulated thread length in meters. The thread speed meter 34 determines the respective thread speed in meters per minute from the pulses of the pulse counter 13 . The multiplier 16 continuously forms a product from the number of pulses supplied by the pulse generators 12 and 13 , for example according to the formula:

Here k is a selected constant, imp. 13 the number of pulses supplied by the pulse generator 13, pulse 12 the number of pulses supplied by the pulse generator 12 . The constant k can remain the same during the entire winding process, but it can also be variable with the number of revolutions of the tree 2 , so that the stored value determined by the multiplier 16 is then equivalent to the respective diameter of the tree 2 .

During the winding process, the braking force control device 8 and the two pressing devices 10 and 11 are set to preselected values. The control of the engine 3 is carried out by the speed-determining device 4 in accordance with the voltage supplied by the generator 43 via the line 44 , that is to say in accordance with preselected values of the thread running speed.

The comparator 19 is inoperative during the manufacture of the first winding. The same applies to the control device 45 . Depending on the position of the changeover contact 40 , the display device 42 either shows the thread running speed, the length of the thread group that has accumulated or the number of turns.

If the predetermined thread length is reached, the winding device 1 is stopped, the tree 2 is stretched out and a new tree is inserted. The products formed in the multiplier 16 after the pulse of the pulse generator 12 and continuously stored in the memory 21 are now decisive as comparison values for all subsequent winding trees. In order to retrieve the stored values in time from the memory 21 , a special clock line 49 can be present between the pulse generator 12 and the memory 21 .

At the beginning of the new winding process, the contact 23 of the switch 20 is switched on. The memory 21 is thereby connected to the comparator 19 . The rotation counter 27 and the thread length counter 28 are set to zero via the clear inputs 31 and 33 . The summers for the pulse sequences which may be present in the multiplier 16 are also set to zero by an erase input 50 . The control device 45 is switched on and at least one of the three operative connections 46 , 47 , 48 is activated. After the engine 3 is switched on, the new winding process then begins. In this way, the multiplier 16 continuously forms products in the manner described above, but these are no longer stored, but only go to the comparator 19 , namely in time with the pulses of the pulse generator 12 . Via the contact 23 the comparator 19 receives the products previously stored in the memory 21 in the same cycle. A resulting difference is forwarded via the line connection 35 , the changeover contact 40 placed on this line connection and the line 41 to the display device 42 and via the branch 41 'to the control device 45 . The control device 45 then influences the braking force control device 8 , the speed-determining device 4 or the two pressing devices 10 and 11 in the sense that the difference determined becomes zero again if possible. The process continues until the second tree has also picked up the predetermined thread length measured by the thread length counter 28 . In between, the changeover contact 40 can always be brought into other positions so that other values can also be read on the display device 42 . The control device 45 remains in the state it was last in, so that larger deviations from the target value are not to be feared if the control device 45 does not take too long to switch off.

The invention is not restricted to the exemplary embodiment shown and described. Instead of a control device 45 , an operator can also be present, who then continuously monitors the display device 42 , actuates the changeover switch 39 and expediently acts on the devices 10 , 11 8 or 4 in the sense that the displayed difference remains small within tolerance limits or completely disappears.

Claims (6)

1.Procedure for the successive production of trees consisting of wound thread sheets, in which each subsequent thread winding is the same as the previous thread winding, in which, during the production of the first winding, the revolutions of the tree are counted continuously by means of pulses and the accumulating thread length is continuously measured by means of pulses and these values can be used to control the subsequent winding processes,
characterized,

• a) that a product is initially continuously formed from the number of impulses per unit of time arising from the speed measurement of the tree and the thread length measurement,
• b) that this product is continuously stored in a memory when the first roll is produced and is continuously input into a comparator when the other rolls are produced,
• c) that the memory is connected to the comparator during the production of the second and all subsequent windings and that the stored products are continuously compared in the comparator with the products which are continuously being obtained,
• d) that the difference resulting from the comparison of the products is displayed,
• e) that either by an operator or by an automatically working device on the thread brakes of the threads to be wound, on the pressing devices of a pressure roller pressing the reel and / or on the speed-determining device of a motor driving the tree in the sense that it acts the difference displayed or determined by the comparator remains within predetermined tolerance limits or becomes zero.

2. Proposal for carrying out the method according to claim 1, with a with the tree ( 2 ) connected to the first pulse generator ( 12 ) for generating the number of pulses proportional to the revolutions of the tree and a measuring roller ( 7 ) driven by the incoming thread group ( 6 ) with a second pulse generator ( 13 ) for generating the pulses proportional to the length of the wound material, these pulses being used to regulate the subsequent winding processes, characterized in that

• a) that the pulse generators ( 12, 13 ) are connected to a multiplier ( 16 ) for product formation of the pulses of the two pulse generators delivered simultaneously per unit of time,
• b) that there is a memory ( 21 ) which can be optionally connected to the multiplier ( 16 ) via a changeover switch ( 20 ) for storing the products formed,
• c) that the multiplier ( 16 ) has a line connection ( 17 ) to a comparator ( 19 ) for determining deviations between the currently formed product and the respectively associated stored product,
• d) that the comparator ( 19 ) can be connected to the memory ( 21 ) via the changeover switch ( 20 ),
• e) that the comparator ( 19 ) has a line connection ( 35 ) to a differential display device ( 42 ) and / or to a control device ( 45 ),
• f) that this control device ( 45 ) has at least one operative connection ( 46, 47, 48 ) to one of the following devices,
• g) a braking force control device ( 8 ) for the thread brakes of the threads to be wound and / or
• h) a controllable pressing device ( 10, 11 ) of a pressing roller ( 9 ) pressing the roll and / or
• i) a speed-determining device ( 4 ) of a motor ( 3 ) driving the tree ( 2 ).

3. Apparatus according to claim 2, characterized in that a revolution counter ( 27 ) is connected to the first pulse generator ( 12 ). 4. Apparatus according to claim 2 or 3, characterized in that a thread length counter ( 28 ) is connected to the second pulse counter ( 13 ). 5. Device according to one of claims 2 to 4, characterized in that a thread speed meter ( 34 ) is connected to the second pulse counter ( 13 ). 6. Device according to one of claims 3 to 5, characterized in that the comparator ( 19 ), the revolution counter ( 27 ), the thread length counter ( 28 ) and the thread speed sensor ( 34 ) each have a line connection ( 35 to 38 ) to a switch ( 39 ), whose changeover contact ( 40 ) is connected to the display device ( 42 ).