DE870979C - Device for carrying out work processes on warping machines - Google Patents

Description

Device for carrying out work processes on warping machines So far, warping machines have to determine the so-called wedge height of the material on the slip drum, namely the material application in the area of the conical end part the slip drum, with the appropriate thread material on a specially designed provided device made a practical experiment and from the determined Calculated values of the wedge height for the warping machine in question or Label drum can be set. This requires both to carry out the Trials as well as the associated computational work relatively large Time expenditure and on the other hand means' waste of material.

Avoiding these disadvantages is the purpose of the invention, which Has a device for the object which is characterized by a group of disks with four as parts of. Differential gears trained, with logarithmic Graduated dials for adjustment purposes, a first one related to the thread count on a given tape width, a second in terms of yarn count, and a third with regard to a set of change gears for the movement connection between the slip drum and the warp thread guide device to be axially displaced for this purpose, which has three dial disks can be blocked, with a die between the second and third dial Sum of their rotary movements absorbing shim is provided, the whole for this purpose, the wedge height of the @ -material application through the fourth dial to display on the slip drum. It thus becomes - the one mentioned The height of the wedge is calculated according to the one on which the slide rule is based Type of invoice. Determined.

The mechanism of this device can be complemented to with the same to be able to determine other work processes on the warping machine, namely the length of the thread wound on the warping drum and the thread speed when writing notes as well as when tree.

Such a designed embodiment of the invention The facility should be explained in more detail using the partly schematic drawing. FIG. 1 shows the device partly in section, FIG. 2 shows parts of a storage device and FIG. 3 shows a sensor device for actuating an electrical switching device.

In FIG. I, i denotes the shaft of the drum 2 with a conical end part 3 intended for receiving and delivering the working threads. This drum 2- is used in a known manner when warping with threads. wound coming from the delivery reels arranged on the slip gate (not shown); in. As a result, these threads are wound onto the warp beam 4, which is driven by a shaft 5. This is parallel to a main shaft 6, which on the one hand by a. Pair of gears 7, 8 the drive of the warp beam shaft 5 and on the other hand by a belt drive 9 the drive of the warp drum: 2 (also called reel). io is an electric drive motor which drives the main shaft 6 via a regulating gear ii, v2, 13. This regulating gear has two cone disks ii and 13, which can be axially displaced relative to one another and which accommodate the Treil® belts 12- between them. One conical disk 13 is subject to the following influences: an axially acting compression spring 14; the other conical disk I i is connected via a coupling body 15 to a regulating lever 17 mounted on a bolt 16, which is in movement connection via a nut i (8 with a threaded spindle i9 an auxiliary shaft 212 in rotary connection, which on the other hand is rotatably connected via a chain wheel 23 and a chain 24 to a chain wheel 25. This wheel 25 forms part of a differential gear and is seated on the hub of a worm wheel 26 which is rotatably arranged on an axle 27 The worm wheel 26 is in motion connection through a toothed ring 26a with a toothed ring of a planetary gear 28, which is eccentrically mounted on the sprocket 25 by means of a pin 29 and engages through a second toothed ring in a central toothed piston 3o of a control drum 31 , which is rotatably mounted on said axis27 The worm wheel 26 is in mesh with a worm 32 which is on a Shaft 33 of a (not shown) electric auxiliary motor is stuck. The toothed piston 3o is firmly connected to the corresponding end wall of the control drum @ el31, which end wall has a ring gear 3.1a on the circumference, which is connected to a gear 3q. a lead screw 35 is engaged, on the threaded part of which there is a nut 36 which carries a shut-off lever 37. According to FIG. 2, the nut 36 is prevented from rotating by a guide spindle 38; the shut-off lever 37 mounted on the nut 36 by means of a pin 39 is intended to interact with a shut-off cam 41 arranged on the control drum 31. The control drum 3i is provided with threaded holes 42; the parking cam 41 is inserted into the corresponding threaded hole of the control drum 31 according to the length of the note in question.

Is on an axis 43 parallel to the axis 27 of the control drum 31 a gear 44 is mounted which meshes with the ring gear 3111 of the control drum 31 stands. A toothed ring 44a provided on the hub of the gearwheel 44 engages Zahgrad45, which is mounted on an axle46 and a cam groove 454 for has a control arm 47 which is attached to a control shaft 48 (see also Fig. e) is; the curve groove 454 is used to determine the logarithm of the revolutions of the Paper drum--. The hub of the gear has a second designated 44b Ring gear, in which a planetary gear 49 engages, which is eccentric by means of a bolt 5o is arranged on a gear 51 mounted on the hub of the gear 44 and also engages in an inner ring gear of a counting wheel 52; this is on mounted on the axis 43 and is used to display the items wound on the slip drum 2 Thread length, for which purpose the counting wheel 52 has a scale on the circumference.

The gear 51 meshes with a gear mounted on the axle 46 53, the hub of which is formed into a worm wheel 534 with which a worm 54 cooperates, which on a shaft 55 of an electric auxiliary motor 56 (Fi.g. 3) is provided. The hub of the gear 53 is also supported by a ring gear 53b with a toothed segment 57 rotatable on the control shaft 48 in engagement on which a two-armed sensor lever 59 is mounted by means of a bolt 58. This ar-. operated by a roller 6o mounted on one arm with a cam track 614 of one Wheel 61 together, which forms a side wheel of a differential gear, which has an intermediate gear 62 and a side gear designated by 63 as well as a from Intermediate wheel62, supported conical planetary gear64, which is equipped with corresponding gear rims of the two side gears Gi and 63 is in engagement. With a toothing that is Extends to part of the circumference of the side wheel 63, a stands on the shaft 48 attached tooth segment 65 in engagement.

The sensor lever 59 carries a stop screw 66 (Fig. 3) for a switching lever 67 on its second arm, which is mounted on the toothed segment 57 by means of a bolt 68 and is used to influence two electrical switches 69 and 70, which are arranged in the circuit of the auxiliary motor 56 are. The sensor lever 59 and the switching lever 67 are connected to one another by a tension spring 71; a force acting on the sensor lever 59. second spring 72 endeavors to keep the sensor lever 59 against the mentioned cam 6111 and move in the direction against the switch 70, the pair of levers 59,67. This sensor device (lever 59, curve 6111) is used to determine the so-called error length, as will be explained in more detail later.

On the axle 43 carrying the counting wheel 52 there is also mounted a group of five disks 73 to 77 which, with the exception of the central intermediate disk 75, have a logarithmic division on the circumference (on a glued-on tape) and represent parts of differential gears; the dials 74 and 76 each carry a conical rotating wheel 78 and 79, which is in engagement with corresponding toothed rings of the discs 73 and 75 or 75 and 77 arranged on the right and left of the respective dial 74 and 76. The dial 73 is related on the number of threads per 1 cm of bandwidth, the dial 74 on the thread number (the graduation has already been corrected by a coefficient K to be taken into account). The dial 76 has reference to change gears and dial 77 to the wedge height of the material application on the slip drum 2. If the dial 73 is set to a given number of threads or its logarithm, then this rotary movement is via the wheel 78 to the middle intermediate disk 75 and from there over the wheel 79 transferred to the dial 77; the intermediate disk 75 and the graduated disk 77 thus perform an equally large rotary movement. If the thread number N or its logarithm is set on the graduated disk 74, the intermediate disk 75 and the graduated disk 77 also rotate by this amount. If a provided (to be selected as required) change gear set or the corresponding logarithm is set by means of the dial 76, then the dial 77 is additionally rotated by the corresponding amount; the intermediate disk 75 remains because the dials 74 and 73 are blocked, as can be seen from the explanations below.

The dials 73, 74 and 76 each have a narrow toothed one Circumferential rim with which a screw 73a or 74a, 76a is used as an adjusting and holding element is engaged. The middle washer 75 is provided with circumferential teeth in engagement with a gear wheel 8o mounted on the axle 46 and on a lateral Flange an internal ring gear Boa for the engagement of the planetary gear 81 of a planetary gear which has a central wheel 82 fixed on the axis 46; the planet gear 81 is arranged by its bearing on the wheel 63 of the differential gear 64 to 61. With a ring gear present on the second side of the wheel 8o is conical Revolving gear 83 in engagement, which is carried by .einem idler gear 84 and further engages a wheel 85; the wheels 84 and 85 of the differential gear thus formed are also mounted on the axle 46. With teeth that focus on one Part of the circumference of the intermediate gear 84 extends, a mounted on the shaft 48 stands Tooth segment 86 in engagement.

On the axle 43 carrying the counting wheel 52 there is also a group of five disks 87 to gi stored, of which the disks 88 and go on the circumference one have logarithmic division. Furthermore, these two disks 88 and go have one. narrow toothed circumferential rim, with which as adjusting and holding element. j e a snail 88a or goa is engaged. The two disks 88 and go each carry a conical one Planetary gear 911 or g3, which is in engagement with the corresponding ring gears arranged on the right and left of the respective dials 88 or go Disks 87 and 89 or 89 and 9i; thus also the disks 8! 7 to gi Part of differential gears. The middle intermediate disk 89 is a chain wheel formed and is by a chain 94 with a fixed on the threaded spindle ig Chain wheel 9.5 in drive connection. There is also a worm wheel on the threaded spindle 96 which cooperates with a screw 97 which is mounted on the shaft 98 .a (not shown) electrical auxiliary motor is stuck.

The above-mentioned disk 87 is rotationally connected by circumferential teeth to a gear 99 mounted on the axle 46, which has a curved track 9911 at the side, with which a control arm cooperates. This is located on a disk ioi which is arranged on the shaft 48 and which belongs to a planetary gear, which also has the two disks io2 and io3 also provided on the shaft 48. The middle disk pulled this planetary gear carries the conical planetary gear 104, which engages in corresponding ring gears of the two lateral disks @ ioi and 103; the middle disk io2 has a toothing on a part of its circumference, with which a locking lever io5 is brought into engagement. can, which can be operated by means of (not shown) pedals. The lateral disk ioi is also operatively connected by a control arm io6 to a control groove 8511 provided on the side of the gear 85. A control arm 107 attached to the side disk 103 cooperates with a side cam track io8a of a gear wheel i o8 which is mounted on the axis 46 and meshes with a circumferential toothing of the disk gli.

The operation and mode of operation of the device described goes proceed as follows, in the order of measuring the on the slip drum 2 wound length of thread, regulating the thread speed when tagging as well as when tree and adjusting the wedge height of the material application on the Paper drum are treated.

The measurement of the thread length wound on the warping drum 2: Assuming the diameter of the warping drum: 2 is the same size, the thread application remains zero, then after a certain number of drum revolutions a warp length of L9 = z - D - n would result, where z denotes the number of drum revolutions and D. denotes the diameter of the warping drum, while Lg denotes the wound length of the thread, called the basic length.

As a result of the application of thread to the warp drum 2, the warp length increases accordingly, increasing the diameter of the warping drum 2 with each revolution 2a increases, where c, denotes the material application per drum revolution.

The more wound warp length is thus Lt = @ca - z2 after z drum revolutions, which is called the error length.

Consequently, the total wound warp length after z drum revolutions is L = Lg -f- Lt.

The material application a depends on the thread number and the number of threads that are wound on a 1 cm tape width. It is a = ä - F, where the value ci corresponds to the thickness: of a thread of thread number N if it were flattened to a width of 1 cm, and F indicates the number of threads per 1 cm of bandwidth. The value d has been determined on the basis of practical tests and is therefore equal to the yarn number times a coefficient determined from these tests.

When the drive motor 1o is in operation, the shaft 6 is driven via the regulating gear 11 to 13 and the slip drum 21 is driven via the belt drive 9, which in turn drives the sprocket 25 via the wheels 20, 21 and parts 22, 23 and 24 as part of the Steuerertromme131 associated differential gear drives. The worm wheel 26 together with the ring gear 26a is held in place by the worm 312 of the auxiliary motor shaft 33; The auxiliary motor itself is only used to reset the counting wheel 52 to zero when the slip drum 2 is stationary and to determine the arrangement of the parking cam 41 on the control drum 311. This auxiliary motor can work in one or the other direction of rotation as required by pressing buttons accordingly. Since the chain wheel 23 is not driven when the drive motor 1o is at a standstill, the counter wheel 52 of the meter counter can be rotated from the auxiliary motor shaft 33.

The rotary movement of the chain wheel 25 is transmitted to the control drum 31 transmitted and passed through the ring gear 31a to the wheel 44, which one Forms part of the differential gear assigned to the counter wheel 52. On that of the warping drum 2 driven by the ring gear 44b and the planet wheel 49 Counting wheel 53 only counts the basic length Lg. By turning the wheel 51 can the Counting wheel 52 are given an additional rotary movement, which corresponds to the error length Lt corresponds, so that the counting wheel 52 makes a total rotary movement according to the value L = the total warp length, which is read on the scale of the counting wheel 52 can be.

The value of the error length must. can be determined by calculation. To perform the multiplication of the factors under consideration mechanically can, the logarithms of the Factors added together, resulting in the value a = material application per revolution the slip drum 2 is determined.

This is done by dials 73 and 74, the first of which (as mentioned earlier) shows the number of threads per 1 cm and the dial 74 the value a '(it is always the thread number belonging to this value on the scale the disk 74 entered). These dials 73 and 74 are by means of the worms 73a and 74a as required with regard to the thread count and thread count in question set; the position of the middle intermediate disk 75 then corresponds to the sum of the rotations of the dials 73 and 74 in accordance with the logarithm of the order a. This value a is via the wheel 8o and the planetary gear 81 of the planetary gear with the stationary central gear 82 and transferred to the gear 61 of the differential gear forwarded to the planet wheel 64.

The intermediate gear 62 called differential gear must! now still around the value log z2 are rotated so that the wheel 61 makes a total rotational movement accordingly the value log Lt or log a -f- log 22 executes.

In order to obtain the value Lt that is to be transmitted to the wheel 51 of the counter must means existing on. Wheel 61 cam 61a log the value Lt are converted, to which the sensor lever is used 59, since excluded a direct transmission for design reasons .

Under. the inflow, the tension spring 72 (Fig. 3), the switch 7o is actuated by the switch lever 67 and thereby the auxiliary motor 56 is switched on, whereupon the toothed segment 57 is rotated via the parts 54, 53a and 53b so that the sensor lever 59 through the roller 6o comes to rest on the cam 61a. As a result of this, the sensor lever 59 is pivoted in such a way that the switching lever 67 is moved away from the switch 70 and the auxiliary motor 56 is thereby switched off. Due to the rotating control cam 61a, the sensor lever 59 will, depending on the requirements, put the switch 70 or 69 into operation and the auxiliary motor 56 will accordingly move the sensor device comprising the lever 59 and the control cam 61a until the switching lever 67 is free between the two switches 69 and 70 is located. The readjustment of the sensor lever 59 by the auxiliary motor 56 is dependent on the play set between the switching lever 67 and the switches 69, 70 . The rotary movement of the feeler lever 59 corresponds to the length of the error; This rotary movement is transmitted by the auxiliary motor 56 via the gears 54, 53a, 53 to the wheel 51 of the differential gear assigned to the counter and is thus added to the basic length Lg set on the counting wheel 52, so that the counting wheel 52 shows the total value of the warp length L.

As already mentioned, the intermediate wheel 6a (Fig. 1) must by the amount log z2, which has to be determined first, since only the value z is known.

The control groove 4511 provided on the wheel 45 is used for this purpose. This wheel 45 is off the slip drum 2 from over the parts 44 and 44a of the Counter driven. The stroke brought about by said control groove 45a gives the logarithm corresponding to the revolutions of the slip drum 2 and is of said control groove 4511 transmitted by the control arm 47 to the control shaft 48, so that over the toothed segment 65 the intermediate gear 62 is rotated by the amount log z2 (since log 22 = 2 - log z, this value can be obtained by simple gear ratio).

During warping, the warping drum 2 drives the control drum 31 via the differential gear with the sprocket 25, and the shut-off lever 37 shifts as its nut 36 moves on the lead screw 35 driven by the control drum 31. When the shut-off lever 37 subsequently strikes a shut-off cam 41 (FIG. 2) of the control drum 31, it actuates the shut-off device of the machine via a switch.

In order to be able to insert the parking cam 41 on the control drum 31 into the relevant threaded hole 42, the auxiliary motor having the shaft 33 is switched on for one or the other direction of rotation by means of pushbuttons (not shown), whereupon the counting wheel 52 is driven accordingly. When the desired length of the slip of paper, which can be read on the counting wheel 52, is reached, the push button must be released, whereupon the named auxiliary motor comes to a standstill. The counting wheel 5, 11 can then be finely adjusted by hand by turning the auxiliary motor shaft 33, whereupon the stop cam 41 is inserted into the threaded hole 42 of the control drum 31 closest to it , according to a mark attached to the stop lever 37.

Since the control drum 31 is in operation of the warping machine from the warping drum 2 is driven off, it remains unaffected by any small inaccuracies with regard to the work of the assigned, serving to determine the error length Sensor device with lever 59 and control cam 6111. It becomes the machine for each slip tape exactly after the predetermined number of revolutions of the Note drum 2 automatically turned off, so that all tapes are practically exactly the same get long.

Keeping the speed of the thread constant: When tagging, the Speed of the warp drum 2, when tree that of the warp beam 4 accordingly the increase in diameter due to the amount of material applied.

Since, for structural reasons, the speed of the warp beam 4 is not measured and cannot be used for the calculation is the respective diameter of the warp beam 4 from the decrease in the diameter of the warp drum: 2 to be determined: For this purpose, the circular area that gives the material applied to the drum is used; the material decrease on the drum 2 corresponds to a certain amount the increase in material on the Kefit beam 4, from which the diameter of the warp beam 4 results. The total order A on the drum 2 corresponds to the order per revolution times the number of drum revolutions.

The value a is already given on the wheel 8o and is transferred to the wheel 85 via the planetary wheel 83 on the intermediate wheel 84 by its corresponding lateral toothed ring. This wheel 85 receives an additional rotational movement by the value log z by means of the control arm attached to the control shaft 48 via the toothed segment 86 and the intermediate wheel 84, so that the total rotational movement of the wheel 85 = log a -i log z = log A is. The cam groove 85a provided on the side of this wheel 85 gives the control arm a rotary movement which represents the content of the circular ring surface of the material applied to the slip drum. This control arm io6, in a manner similar to the toothed segment 57, is assigned an electrical switching device (not shown) for an auxiliary motor (in the sense of FIG. 3) with a switching lever which is influenced by a sensor device (lever and control cam). It corresponds to the feeler lever 59 provided according to FIG. 3 and the control arm ioo cooperating with the cam track 9911 according to FIG. A difference compared to the first sensor device lies in the second. before, when the control arm lio6 drives the arm ioo, which acts as a sensor lever, directly and the control cam 9911 provided on the wheel 99 is readjusted from the auxiliary motor shaft 98 via the threaded spindle i9, the chain gears 95, 94, 89 and the disks 88 and 87 is, in contrast to the previously described first sensor device, in which the cam is driven and the sensor lever is readjusted. The sensor lever ioo is used to switch on the auxiliary motor shaft 98 for the purpose of controlling the regulating gear ii to 13 to determine the speed of the warping drum 2.

The stroke of the cam path gga also corresponds to the value of the annular surface of the material applied to the drum e, and it is designed in such a way that its rotation about the d axis 46 corresponds to the log D ..1 .. 2z11.

The rotation of this cam path gga shows how many times smaller the speed must be A for a specific job.

As already mentioned, the cam track gga is readjusted Auxiliary motor shaft 98 rotated from the threaded spindle i9, so that the nut 18 around the same value as the cam track g911 and thus the corresponding via the regulating lever 17 Conical disk i i of the regulating gear i i shifted to 13 and thereby the speed the shaft 6 is changed. The Konnsplatten i i and 13 of this regulating gear are designed in such a way that the displacement of the disk i i also corresponds to the logarithm corresponds to the change in speed.

The graduated disk 88 (FIG. I) belonging to a differential gear has a scale with logarithmic graduation on its circumference for determining the working speed when labeling. By turning this dial 88, the middle disk 89 is held when the auxiliary motor shaft 98 is at a standstill; The cam track gga is rotated via the planetary gear 92 and the wheels 87, 99 and the auxiliary motor which has the shaft 98 is switched on by the sensor lever ioo and its switch, so that via the threaded spindle rg, the chain gear 9,5, 9'4, 8 '9 and the wheels 92. "87 the wheel 99 with the cam track gga is rotated back into the starting position. The threaded spindle ig and .through this the regulating lever 17 and thus the regulating gear ii to 13 are adjusted in such a way that the shaft 6 _ assumes a speed corresponding to the speed set on the basis of the scale of the disk 88.

To keep the thread speed constant when tree is one further switching device with a switching lever and associated sensor device intended.

The lateral wheel io3 is driven by the control arm loh via the wheel ioi and the planet wheel ia4 on the intermediate wheel 102, Idas carries the sensor lever 1 07 , which is used to switch on the auxiliary motor shaft g8 for the purpose of controlling the regulating gearbox ri to 13 for determination the speed of the warp beam 4. When tree is also from the auxiliary motor shaft 98 via the threaded spindle iizg,. The chain gear 95, 94, 89 and the wheels 93 and 9i provided with the cam track io8a wheel io8, with the regulating gear ii to 13, the shaft 6 and the pair of wheels 7, 8, the speed of the warp beam 4 is changed in such a way that the peripheral speed or the thread speed remains constant. The scale disk 9o belonging to a differential gear has a scale with logarithmic graduation on the circumference to determine the working speed when trees.

The working speed for marking out as well as for treeing can be can be set in advance by means of the disk 88 or go. - By one, not - Switch is, depending on the requirement, the circuit of the one or other regulating system and accordingly the corresponding working speed is set.

So that the sensor # Iiebel107 is in the starting position for regulating the trees at the start of work, the locking lever io5 is disengaged from the intermediate gear ioz by means of the provided pedal when the machine is started, whereupon the wheel 103 is disengaged by a (not , drawn) tension spring is pulled into the starting position. When the machine is switched off, the locking lever io5 comes into engagement again with the intermediate wheel im, whereby this is blocked and remains in its position when tree, so that the sensor lever 107 arranged on the wheel 103 is driven by the control arm io6 via the planetary gear 104 mounted on the intermediate wheel io2 will. Determination of the wedge height of the material application on the slip drum: In order to now determine the wedge height to be determined at the slip drum for the material application, the value a (material application per revolution of the slip drum) or its logarithm, which, as already described, must be at the intermediate wheel 75 (Fig. I) will still be multiplied by the number of revolutions of the slip drum, from which follows: a - z = A = total application = K (wedge height) Since the axial movement or displacement of the tape in the area of the conical end part 3 the warp drum 2 is the same size for each warp length, i.e. the wedges forming the cone of the drum are always used, the number of drum revolutions = Z = warp length divided by the drum circumference. In order to obtain the entire shift for each chain length, changing gears must be provided and used as required; these change gears (not shown) serve .the movement connection between the warping drum and the guide device to be axially displaced for this purpose with the guide sheet for the threads to be fed to the warping drum. Hence: The change gear set can thus be adjusted on the basis of the scale of the disk 76. The rotary movement of the disk 76 continues on the disk 77, likewise the value a from the intermediate disk 75 via the planetary wheel 7g carried by the graduated disk 76, so that the disk 77 rotates by the full amount and thus the wedge height on its scale can be read.

So far, warping machines have been used to measure the effective length of the label Serving devices become known in which, the threads around guide rollers as well as must be guided around a measuring roller driving a meter counter, which means a very severe handicap for the operator. The measuring roller must have as large a diameter as possible so that their speed remains low, otherwise there is a risk that the measuring rollers will not be fast enough when the machine is switched off comes to a standstill in order to avoid major measuring errors.

It is also known to keep one constant on the warping machine to arrange the thread speed when trees serving regulating device, wherein in turn a measuring roller (with its own disadvantages) is provided, which the Drive a speedometer is used. The speedometer indicates when a predetermined speed-an electrical contact closed, whereby in the Follow the regulating device is kept in operation until the normal working speed is present; disadvantageously. the regulating device if the working speed is too low not put into operation. A re-ulier device for the thread speed when labeling is not available, what so far. has a very adverse effect than with the increase in the thread speed the thread tension increases excessively.

All these disadvantages are in the case of the described, within the meaning of the invention trained facility avoided. This facility, in general can be carried out in various ways with regard to details, if desired limited in their construction to the means used to determine the height of the wedge serve the material order on the slip drum; these means are at the described Embodiment parts 73 to 79.

Claims (6)

PATENT CLAIMS: i. Facility for carrying out work processes on warping machines, characterized by a disc group (73 to 77) with four designed as parts of differential gears, provided with logarithmic graduation Dial discs (73, 74, 76, 77) for adjustment purposes, a first (73) with respect to the Thread count on a given bandwidth, a second (74) in terms of thread count and a third (76) relating to a change gear set for movement connection between the warp drum (2) and the warp thread guide device to be axially displaced for this purpose, which three dials (73, 74, 76) can be blocked, with between the second and the third dial disk is an intermediate disk that absorbs the sum of their rotational movements (75) is provided, the whole for the purpose, through the fourth dial (77) the To display the wedge height of the material application on the slip drum (2). 2. Device according to claim a, characterized in that the disk group (73 llis 77) is in working connection through its intermediate disk (75) with means which are used for measuring. the thread length wound on the slip drum (2) and the regulation of the thread speed when tagging and tree are used and each have a sensor device (59 or ioo, io7) for each of these three functions, which be from the warping drum (2) Influences, a speed regulating gear (ii to 13) is inserted into the motor drive (io), the sensor device (59) assigned to the first function (measuring the thread length) controlling an auxiliary motor (56) to turn one of the warping drum (2) to transmit from the driven counter (5i2) a computational auxiliary factor (error length) required for the orderly work flow, whereas the two other sensor devices (ioo, io7) control an auxiliary motor (98) which controls the mentioned speed regulation, -uli: gear (ii to 13), these two sensor devices (ioo, 107) each having a lockable dial (88 or 9o) provided with logarithmic graduation for setting purposes h is assigned to the thread speed when tagging or trees, which two dial disks (88, 9o) are designed as parts of differential gears which are in working connection with the mentioned speed regulating gear (ii to 13). 3. Device according to claims i and 2, characterized in that the Counter has a counter wheel (52) that can be driven via a differential gear (44, 49) and is in working connection with a control drum (31) with which a lever (37) cooperates, which is connected to the parking device of the machine, and that the control drum (31) in turn via a differential gear (2'5, 2'8, 30) is driven by the slip drum (2) and for setting purposes by means of an auxiliary motor assigned to it (via 33) can be rotated for itself. 4. Establishment according to claims li to 3, characterized in that each of the three sensor devices (59, Zoo, 107) has a lever used to control the associated auxiliary engine, who works with a control track. 5. Device according to claims i to .4, characterized in that the first function (measuring the thread length) associated sensor device (59) via a. Differential gears (61 to 64) and a planetary gear (8i) with the intermediate disk (75) of the disk group (73 to 77) is in working relation. 6. Device according to claims i to 5, characterized in that the two sensor devices (ioo, 107) assigned to the second and third function (thread speed when warping and trees) via a differential gear with the intermediate disk (89) of the disk group (87 to 9o) Are in. Working connection and both sensor devices are connected to a common planetary gear (1O1 to 103) .