EP0978581A2 - Textile processing machine with a drawing frame unit - Google Patents

Abstract

The comber assembly (1), with a following two-stage drawing unit (6) to process the combed fibers (8), has a controlled speed for the paired entry rollers (42) at the second drawing stage (II). The roller speed is set through a signal from a monitor (30) for the drawn fibers (12) from the first drawing stage (I). A sliver buffer (3) is between the drawing stages (I,II). The paired outlet rollers (11) at the first drawing stage (I) have a controlled drive (M3), and its paired inlet rollers (10) are coupled to the drive (M1) of the textile machine (1). The drive motor (M1) for the textile machine (1) and the drive motor (M2) for the paired entry rollers (10) of the first drawing stage (I) are controlled by a common frequency converter (20). The transmission for the paired entry rollers (10) of the first drawing stage (I) is linked to the transmission (14) of the textile machine (1). The drawing stages (I,II) have separate drive motors (M3,M5). The machine drive motor (M1) acts as a master for the drive motor (M3) for the paired exit rollers (11) of the first drawing stage (I) and for the drive motor (M5) for the second drawing stage (II). A number of combing heads, at the comber (1), are in front of the drawing stages, with a separate drive motor for their lap rollers, with a speed controlled by the monitor (30) signals. A sliver laying unit (60) is after the drawing unit (6), to lay the drawn sliver (9). The drive (50,51) for the laying system is coupled to the transmission (47) for the paired exit rollers (43) of the second drawing stage (II). Sensors (S1,S2) at the sliver buffer (3) are connected to the control for the drive motor (M5) for the second drawing stage (II), which in turn controls the sliver buffer. The sliver buffer (3) forms a suspended sliver loop (FS), with at least one sensor (S1,S2) to register the loop. A further pair of rollers (40) is between the sliver buffer (3) and the monitor (30), with a drive (27) linked to the drive (38) for the paired entry rollers (42) at the second drawing stage (II). A monitor (57) for the drawn sliver (9) is between the second drawing stage (II) and the sliver laying unit (60). The sliver laying unit (60) has a separate electric drive motor, controlled by the drive motor (M5) for the second drawing stage (II), through a frequency converter.

Description

The invention relates to a textile processing machine for processing Textile fibers, the amount of fibers formed after processing being passed on to a subsequent at least two-stage drafting unit to form a uniform Sliver is discharged and between the first and second drafting stage Measuring device is provided for recording that combined after the first drafting stage Fibers and that from the measuring device to the control unit Measurement signal for the intervention in the drive of the second drafting unit stage Compensate for short-term fluctuations in mass in relation to specified ones Setpoints are used, the long-term detected by the measuring element Mass fluctuations in the amount of fibers in the area behind the measuring element compensated become. The term "behind the measuring element" is related to the direction of conveyance of the fiber mix.

A combing machine can be found in EP-B1 376 002, the combing units a regulating drafting device is arranged downstream, in which a uniform sliver is formed from the fiber material delivered by the individual combing heads, which is then placed in a receptacle via a storage device becomes. A measuring element is arranged in front of this regulating drafting device to record the to the subsequent drafting system. This measuring organ captured the unevenness of the supplied fiber mass and solves in connection with one Setpoint comparison a control intervention in the drive unit from with a corresponding Distortion changes to compensate for unevenness in the fiber mass.

To intervene in the control interventions in the area of the input roller of the drafting system, is proposed here a tape storage between the feed roller and To provide combing devices.

The desire for ever higher production rates inevitably results also an increase in the processing speed of the fiber material and also higher Requirements for the measuring device to detect mass fluctuations. This is particularly the case if, for example, the solder joints of the Combs emitted fiber material are detected by the measuring element have to.

It was therefore proposed in EP-A2 799 916 that the combing devices to design a downstream drafting system in two stages. With this facility is provided, the sliver mass reduced by the first stretching process between the two drafting stages. This makes it possible in the after the first drafting stage, the thinned sliver mass present for a short time to better and more accurately detect occurring mass fluctuations (e.g. solder joints), in order to be able to regulate this at the second drafting stage. The regulation The long-term fluctuations in mass occur after the second drafting stage by changing the speed of the output roller pair of the first Drafting stage. The drive connections are made by the drive connections provided Depositing device, and the drive of the rear two pairs of rollers of the second The drafting stage is dragged through the control interventions of the long-term regulation.

Likewise, the speed of the pair of output rollers of the second drafting stage must be be adjusted so that the draft ratios in the second drafting stage not be changed by it. This requires an increased control requirement in the second drafting stage, especially here the brief mass disturbances (e.g. solder joints) must be compensated.

The object of the invention is therefore to improve the known devices, to get a device to do with simple and inexpensive means to enable the production of a high quality and even sliver.

This object is achieved in that the speed of the input roller pair of second drafting stage is controlled according to the signal of the measuring element and a sliver store is provided between the drafting units.

This enables the short-term fluctuations in the delivery speed the fiber mass and possibly also long-term fluctuations in the sliver storage to catch, which is a tracking of the comber drive or Drive of the tape storage is unnecessary. This arrangement also ensures an optimal one Regulating short-term fluctuations in mass (e.g. solder joints), as these can be better recorded by measuring the reduced fiber mass.

By proposing that at the first drafting stage, the pair of output rollers is driven with an adjustable drive and the input roller pair with is coupled to the drive of the textile machine, the tensioning delay of the textile material kept constant between the textile machine and the drafting unit.

It is further proposed that the drive motor of the textile processing machine and the drive motor of the input roller pair of the first drafting stage a common frequency converter can be controlled.

This results in a constant tension in the fiber mass between the textile processing machine (e.g. comber) and the following first Drafting unit guaranteed. As a result, there is no more memory between the textile processing machine and the first drafting unit is.

Preferably, the drive of the input roller pair can be carried out directly with the gearbox be coupled to the textile processing machine.

It is further proposed that the drafting units each have a separate one Drive motor to be driven.

This ensures the use of a clear and safe drive system.

In order to match the drive to one another, it is proposed that the drive motor the textile processing machine as a guide motor (master) for the drive motor of the pair of output rollers of the first drafting stage and the drive motor of the second drafting stage is formed. These drive motors become the lead motor, especially with regard to a basic speed, tracked as a "slave".

Furthermore, the textile processing machine is proposed as a combing machine form, the winding rollers of the combing heads with a separate drive motor be driven, its speed according to the signal of the measuring element is regulated. Such an embodiment for controlling drifting in the fiber mass has already been described in EP-PS 558 719. This allows long-term regulation done directly on the comber.

It is further proposed that the second drafting unit have a depositing device is subordinate to the sliver formed and the drive of the depositing device is coupled to the drive of the second drafting unit. This coupling takes place in particular with the drive of the pair of output rollers of the second drafting unit. This allows constant drive conditions to be maintained.

Furthermore, it is proposed that the memory between the two drafting units is equipped with a monitoring device that works with the controller of the drive motor of the second drafting unit is connected.

It is proposed that the control of the drive motor of the second drafting unit, or the basic speed of the drafting unit II, by the signal of Monitoring device of the memory can be overridden. Once the sliver loop is detected by a sensor, the readjustment of the speed of the Drive motor step by step (e.g. in steps of 3% of the speed) until the loop is again within the tolerance range. A timer can also be provided be that the machine switches off if the loop is longer than a predetermined one Time is outside the tolerance range.

This provides an additional safety device, especially if the storage filling (e.g. the sag in the storage) one way or the other Side drifts. This can have various causes, for example if based on any malfunction the tracking of the drive motor of the second drafting unit to the drive motor of the textile processing machine is disturbed.

The storage between the drafting units can be implemented as a sag storage be, wherein at least one scanning element is provided to the fiber ribbon slack to feel.

So that the sliver passed through the measuring element under a constant Tension delay, it is proposed that between the memory and the Measuring element another roller pair is arranged, the drive with the input roller pair the second drafting stage is directly coupled. This excludes that the control interventions can affect the measuring process.

For security reasons, it is also proposed that between the tape storage and the second drafting stage a monitoring element for the sliver delivered is arranged. This monitoring element more or less adjusts last control instrument before the sliver is placed in a subsequent jug becomes. The monitoring element is with a limit range or tolerance field fitted. As soon as the delivered sliver is outside this tolerance range the entire system is switched off. Of course, timers can also be used be provided, the function of the monitoring element over a certain period of time stop. This is particularly necessary if the textile processing Machine is started with a new batch of material and started again must become. Instead of a timer, it would of course be conceivable to start up perform this monitoring element manually.

Furthermore, it is proposed that the storage device have a separate electric drive motor is driven with the drive motor of the second Drafting stage is controlled by a common frequency converter.

Fig. 1

eine schematische Seitenansicht einer Kämmaschine mit einer erfindungsgemäss vorgeschlagenen Anordnung einer nachfolgenden Streckwerkseinheit,

Fig. 2

ein weiteres Ausführungsbeispiel in der Antriebsführung entsprechend Fig. 1,

Fig. 3

eine schematische Seitenansicht eines weiteren Ausführungsbeispiels entsprechend Fig. 1,

Fig. 4

eine schematische Darstellung eines Diagrammes, welches sich durch die Messergebnisse des Messorgans ergibt,

Fig. 5

ein vergrösserter Teilausschnitt entsprechend den Fig. 1 bis 3 und

Fig. 6

eine schematische verkleinerte Teilansicht entsprechend dem Ausführungsbeispiel nach Fig. 1 mit einer geänderten Antriebsführung für den Antrieb der Bandablage.

Further advantages of the invention can be gathered from the exemplary embodiments shown and described below. Show it:

Fig. 1

2 shows a schematic side view of a combing machine with an arrangement of a subsequent drafting unit unit proposed according to the invention,

Fig. 2

another embodiment in the drive guide according to FIG. 1,

Fig. 3

2 shows a schematic side view of a further exemplary embodiment corresponding to FIG. 1,

Fig. 4

1 shows a schematic representation of a diagram which results from the measurement results of the measuring organ,

Fig. 5

an enlarged partial section corresponding to FIGS. 1 to 3 and

Fig. 6

a schematic reduced partial view corresponding to the embodiment of FIG. 1 with a modified drive guide for driving the tape storage.

In Fig. 1 the longitudinal part of a combing machine 1 is shown, on which cotton roll 4th for unrolling and combing out by subsequent combing devices. In As a rule, eight such coils are placed on a combing machine for unrolling.

The slivers formed in the individual combing heads are placed on a conveyor table FT (schematically indicated) combined on the longitudinal part 2 to form a fiber composite 8 and in the conveying direction F of a first drafting stage 1 of one Drafting unit 6 fed.

The slivers emitted by the individual combing heads usually have a number or sliver mass of approx. 8 g / m, whereby the sliver composite 8 from eight slivers with a total mass of 64 g / m. This mass of fibers is subjected to a five-fold delay in drafting stage 1, whereby the fiber mass released from drafting unit stage 1 is reduced to approximately 12 g / m is reduced.

In the examples described in FIGS. 1 to 3, the drafting stages 1 and II each with only one delay zone, or with only two consecutive ones Roller pairs shown in simplified form. The main default zone shown is in many versions upstream of a pre-draft zone, whereby another pair of rollers is necessary, as was also shown, for example, in EP-A2 799 916. With such a training, the input regulation (drafting system stage II) the advance or the speed ratio of the two rear roller pairs is constant kept while the speed of both pairs of rollers simultaneously compared to the front and constant rotating pair of rollers (during control intervention) is changed.

The delay in the first drafting stage 1 takes place between the pair of input rollers 10 and the pair of output rollers 11 instead. The lower rollers of these roller pairs are connected to a drive. So the input roller pair 10 by one Motor M2 driven by a gear 13. The motor M2 is via a control line 14 connected to a frequency converter 20, which is controlled by a control unit S. becomes. The frequency converter 20 is also used via the line 16 Main motor M1 driven, which drives the combing machine 1 via a gear 17. The The lower roller of the output roller pair 11 is driven by a motor M3 and a transmission 24, the motor M3 via the control line 26 with the control unit S is connected. Another pair of rollers 5 is the pair of output rollers 11 downstream, coupled via the path 36 to the drive of the pair of rollers 11 is. The roller pair 5 provides the input roller pair to a subsequent sliver store 3 that. The roller pairs 10, 11 each have a speed sensor 18 or 22 assigned to the signals via the lines 19 and 39 to the control unit S submit.

The sliver storage 3 is designed as a sag storage and at its output provided with a further pair of rollers 40. For sag detection is the Memory 3 equipped with sensors S1 and S2, each of which the position of the sliver loop Monitor FS. The sensors S1 and S2 are connected via line 35 to the Control unit S connected. The drive of the pair of rollers 40 is via the drive path 27 removed from the drive path 38, which for the controlled drive of the Input roller pair 42 of the subsequent drafting stage II is responsible.

The pair of rollers 40 is followed by a measuring element 30, which has the signals determined outputs to the control unit S via the path 31. The measuring element can be used with a be equipped with inductive sensors or with grooved rollers. In connection the second drafting stage II is arranged on the measuring element 30 and is equipped with a Input roller pair 42 and an output roller pair 43 is provided. The lower one Roller of the pair of input rollers 42 is driven by a differential gear 45, which is connected to a gear 47. The differential gear 45 can by a Control motor M4 can be overridden. The control motor M4 is via the control line 48 controlled by the control unit S. The drive of the lower roller of the pair of rollers 43 takes place via a drive path 37, from the transmission 47, which is via the motor M5 is driven. The motor M5 is via the control line 70 to the control unit S connected.

The transmission 47 drives the transmission 50 via the drive path 52, from which the calender rolls are driven via the schematically illustrated drive path 51 53 the funnel wheel 54 and the can plate 55 of a depositing device 60 are driven become. The drive paths are shown only schematically on the representation of others Translation or reduction elements have been omitted for reasons of clarity.

The sliver that is formed is in the depositing device 60, also called the sliver depot 9 placed in a loop K in a loop shape.

Between the pair of output rollers 43 of the second drafting stage II and the calender rollers 53 of the tape storage device 60, a monitoring element 57 is additionally arranged, which is connected to the control unit S via the path 58. This monitoring element 57 has the task of shutting down the entire machine when the sliver mass is outside a specified tolerance range.

The function of the system according to FIG. 1 is as follows:

The sliver assembly 8 released by the combing machine 1 becomes the drafting stage 1 fed and warped there for example five times. The speeds of the roller pairs 10 and 11 are scanned by the speed sensors 18 and 22 and the Control unit S transmitted. By controlling motor M1 and motor M2 The synchronism between the combing machine units is via the same frequency converter 20 and the input roller pair 10 ensures a constant Tension delay in the fiber ribbon composite 8 is maintained. The drive motor M1 for the comber represents the setting of the basic speeds of the Systems represents the "master", which, via the control unit S, the motor M3 for the drive the first drafting stage 1 and the M5 motor for driving the second drafting stage II and the tape storage device 60 as a "slave" with a predetermined basic speed ratio be tracked. The ratio between The engines M1 and M3 are determined by the level of control intervention in the engine M3 changed, this deviation from the ongoing tracking of the Base speed of motor M3 is added (with a positive or negative sign). The nonwoven fabric 28 formed in the first drafting stage 1 becomes a sliver 12 summarized and passes through the pair of rollers 5 in the sliver storage 29. The sliver is guided in the sag as a loop FS and over the roller pair 40 is withdrawn from this memory 29. The position of the loop FS is monitored by sensors S1 and S2. As soon as one of the sensors S1 and S2 if the sliver loop FS is detected, a signal is sent via line 35 to the control unit S delivered. Depending on the type of signal (loop moves outside of Sensor range up or down), the basic speed of the M5 motor is corresponding changed and thus the withdrawal speed of the pair of rollers 40th This changed speed of the motor M5 is maintained until the Loop is again within the range of the two sensors S1 and S2. If feedback is not possible, there is a fault in the overall system and the system (combing machine 1 and drafting unit 6) is shut down. This can be about a timer, not shown, which is integrated in the control unit S and which The task is to monitor the time in which the sliver loop FS is outside the area of sensors S1 and S2. Will be a given time exceeded, this leads to the shutdown of the system described above.

If, for example, the error lies in an incorrectly supplied number of tapes, so 5, after the pair of rollers 5 in a container B can be deposited until a predetermined delivery is reached again of fiber material is guaranteed. The sliver storage 3 could (not shown) with a closable delivery opening.

The values determined in the measuring element are sent to the control unit S via the path 31 dissipated and compared there with a target value (target). The deviations (long-term) Regarding compliance with the sliver number, the control unit S determined and depending on the size of the deviation corresponding control pulses delivered to the motor M3 for changing the speed of the output roller pair 11. Resulting changes in the conveying speed of the sliver 12 are caught in the storage 3 via the sag of the sliver loop FS. The tracking of the basic speed of the M5 engine when recording the changed Loop FS through sensors S1 or S2 has already been described previously. The Change of warpage between rollers 10 and 11 in the first drafting stage 1 again serves to return the sliver mass to a predetermined one Setpoint within a tolerance range. Sampling the speeds over the Sensors 18 and 22 of the roller pairs 10 and 11 are used for monitoring and compliance of predefined delay ratios and thus determines the drive ratio of motors M3 to motors M1 and M2. For example, M1 is used as "Master", which the motors M3 and M5 with respect to the basic speed as "Slave" to be tracked. After passing through the measuring element 30, this arrives Sliver 12 in the draft zone of the second drafting stage II between the Roller pairs 42 and 43. The draft ratio between these two roller pairs the second drafting stage can be influenced via the differential gear 45, which is overridden by the M4 control motor. This override then occurs if the short-term fluctuations determined by the measuring element 30 are outside move a predetermined tolerance range and must be adjusted. The control motor M4 receives its control pulses via path 48 and changes via the gear 45, the speed of the input roller pair 42 of the second drafting stage II. Highly dynamic control motors are used for this control intervention. The regular use is delayed. This means that time must be taken into account be, which the measured and to be regulated point of the sliver 12 from Measuring element 30 up to a control point of use between the roller pairs 42 and 43 has traveled.

The interventions in the resulting from the speed changes of the pair of rollers 42 Conveying speed of the sliver is retroactive through the memory 3 caught. Because the speeds of the pair of rollers 40 and the pair of input rollers 42 cover, the tension of the sliver remains in the measuring element 30, the is the same or constant between these roller pairs. From this arise no additional interference on the actual measuring process.

The sliver 9 formed in the second drafting stage II passes through a monitoring device 57 to the calender rolls 53 of a tape storage 60, where there is a Funnel wheel 54 is placed in a can K in a loop shape.

The embodiment of Fig. 2 shows a similar device as in Fig. 1, wherein instead of the electrical coupling of the two motors M1 and M2 via the frequency converter 20 there is a mechanical drive linkage. The Drive the input rollers 10 of the first drafting stage via the drive path 15 removed directly from the gear 17 of the combing machine. This makes it constant Drive ratio guaranteed. The other facilities correspond to the example 1 and have already been described there. An additional speed monitoring The two pairs of rollers 10 and 11 are not provided here, especially since one is fixed mechanical coupling of the input roller 10 is present.

The implementation of the fiber mass by the drafting unit 6 and the implementation the control interventions correspond essentially to the sequence already described for the exemplary embodiment corresponding to FIG. 1.

In Fig. 3 another embodiment is shown where the drafting stage 1 with a constant working delay. This means that there is no rule intervention to compensate for long-term drift in the sliver mass. The drive the drafting unit stage 1 takes place via the motor M3, which drives a gear 24, from which the drive connections 23 and 29 to the roller pairs 10 and 11 to be led. From the drive path 29, the drive path 36 is removed, the one makes fixed drive coupling between the pairs of rollers 11 and 5. The aggregates, which follow the pair of rollers 5 correspond to the embodiment already described in Fig. 1, whereby reference is made here. Is behind the pair of input rollers 10 a combing head 7 (of a total of 8 combing heads) of the combing machine 1 is shown schematically. The combing head 7 is 90 ° with respect to the subsequent drafting unit 6 drawn in the horizontal twisted, which is particularly evident from the representation of the Fiber composite 8 can be seen in a triangular shape.

With this version, the long-term mass deviation is compensated (see Fig. 5) by changing the speeds of the winding rollers 58 and 59, which Driven via the drive path 61 by the gear 62 or by the drive motor MW become. The drive motor MW receives its control pulses via line 77 by the control unit S and is readjusted in accordance with the signal of the measuring element 30. By changing the speeds of the winding rollers 58 and 59 changes the tension in the wadding W, which is unwound from the winding 4 and one subsequent pliers unit 63 is supplied. The pliers unit 63 will driven by the main motor M1 via the transmission 17 and the drive path 66. The drive motor M1 is controlled via the control line 16 by a frequency converter 20, which also the drive motor M3 already described controls.

The drive 1 likewise drives the drive 17 via the drive path 65 Round comb 64 and the tear-off cylinder pair 67 following the pliers unit via the drive path 68. That of the tear-off cylinder pair 67 (as a rule, two such Tear-off cylinder arranged one behind the other) delivered fiber fleece 71 is over transfers a fleece table 72 to a funnel 75, in which a sliver is made the fleece 71 is formed. This sliver is on the conveyor table shown schematically FT filed and forms with those given by the other combing heads Sliver a sliver composite 8, which to the pair of input rollers 10 subsequent drafting unit I is transferred.

The term that the long-term mass fluctuations in the amount of fibers in the area "behind" the measuring element is in relation to the conveying direction F based.

By changing the speeds of the winding rollers 58 and 59 based on the signal of the measuring element 30, the tensioning of the cotton wool W between the winding roller 59 and the subsequent pliers unit 63 changed, which changes the Size of the delivered sliver mass changes. Further explanations on this change in drift can be found in published EP-558 719. The regular interventions in the second drafting stage II and the tracking of the basic speed of the drive motor M5 based on the sensors of the sliver storage 3 correspond to that Embodiment according to FIG. 1, but this will not be discussed in more detail here.

With this version you get a device, with long-term fluctuations can be balanced with existing facilities, the Drafting stage I can be operated with a constant draft ratio.

Of course, there are other design variants in the drive system possible, which can serve to carry out the principle of the invention.

4 is based on an evaluation diagram of a measured fiber sliver 12 depicts what is termed short-term and long-term fluctuations in mass is to be understood. The mass m is plotted over time t. The brief mass fluctuations (e.g. due to the soldering points on the combing machine) generate certain peaks in the diagram but essentially move around that horizontal tolerance field T. Is there a long-term LZ drifting of the sliver mass before, the tolerance field T migrates from a horizontal plane, as shown by the Dashed area is shown schematically. This long-term stripping of the sliver does not occur suddenly (except in the event of a belt break) but moves for a long time. That means the regulation of such a long-term drift does not require highly dynamic readjustment of the drive of the drafting rollers.

6 shows a reduced partial section corresponding to FIGS. 1 to 3 with a modified drive guide for the tape storage 60. The drive of the Transmission 50 from a separate drive motor M6, which via the control line 78 is controlled by a frequency converter 79. At the same time, this frequency converter 79 via the control line 76, the drive motor M5 for the second Drafting unit stage II driven. The other units already correspond to the version, as described for example in Figures 1 to 3. Through the control A constant drive ratio is established via the same frequency converter 79 guaranteed between the tape storage 60 and the pair of output rollers 43.

Claims (15)

Textile processing machine (1) for processing textile fibers, the after the amount of fiber (8) formed during processing to at least one subsequent one two-stage drafting unit (6) to form a uniform sliver (9) is discharged and between the first and second drafting stage (I, II) Measuring element (30) is provided for detecting that after the first drafting stage (I) summarized fiber material (12) and that from the measuring element (30) to one Control unit (S) output measurement signal for intervention in the drive of the second Drafting unit level to compensate for short-term mass fluctuations in the Relationship to specified target values (target) is used, the by the measuring element recorded long-term fluctuations in the mass of fibers in the Area behind the measuring element, characterized, that the speed of the input roller pair (42) of the second drafting stage (II) is controlled according to the signal of the measuring element (30) and between the drafting stages (I, II) a sliver store (3) is provided. Textile processing machine according to claim 1, characterized in that at the first drafting stage (I) the pair of output rollers (11) with an adjustable Drive (M3) is driven and the input roller pair (10) with the drive (M1) of the textile machine (1) is coupled. Textile processing machine according to claim 2, characterized in that the Drive motor (M1) of the textile processing machine (1) and the drive motor (M2) of the input roller pair (10) of the first drafting stage (I) via a common frequency converter (20) can be controlled. Textile processing machine according to claim 2, characterized in that the Drive (15) of the input roller pair (10) with the gear (17) of the textile processing Machine (1) is connected. Textile processing machine according to one of claims 1 to 4, characterized in that that the drafting stages (I, II) each have at least one separate one Drive motor (M3, M5) can be driven. Textile processing machine according to one of claims 1 to 5, characterized in that that the drive motor (M1) of the textile processing machine (1) as Guide motor (master) for the drive motor (M3) of the pair of output rollers (11) the first drafting stage (I) and for the drive motor (M5) the second Drafting stage (II) is formed. Textile processing machine according to claim 1, characterized in that the Drafting unit (6) upstream of several combing heads (7) of a combing machine (1) are. Textile processing machine according to claim 7, characterized in that for the winding rollers (58, 59) of the combing heads (7) a separate drive motor (MW) is provided, the speed of which corresponds to the signal of the measuring element (30) is regulated. Textile processing machine according to one of claims 1 to 8, characterized in that the drafting unit (6) has a depositing device (60) for the formed Sliver (9) is arranged downstream and the drive (50, 51) of the depositing device with the drive (47) of the pair of output rollers (43) of the second drafting stage (II) is coupled. Textile processing machine according to one of claims 1 to 9, characterized in that that the sliver storage (3) with a monitoring device (S1, S2) is equipped with the control of the drive motor (M5) of the second Drafting stage (II) is connected. Textile processing machine according to claim 10, characterized in that the Control of the drive motor (M5) of the second drafting stage (II) by the signal the monitoring device (S1, S2) of the sliver storage can be overridden is. Textile processing machine according to one of claims 1 to 11, characterized in that that the sliver storage (3) as a sag storage with at least a scanning element (S1, S2) for the sliver sag (FS) is. Textile processing machine according to one of claims 1 to 12, characterized in that that between the sliver store (3) and the measuring element (30) a further pair of rollers (40) is arranged, the drive (27) with the drive (38) of the input roller pair (42) of the second drafting stage (II) coupled is. Textile processing machine according to one of claims 1 to 13, characterized in that that between the laying device (60) and the second drafting stage (II) a monitoring element (57) for the delivered sliver (9) is arranged. Textile processing machine according to one of claims 9 to 14, characterized in that the storage device (60) via a separate electrical Drive motor (M6) is driven by the drive motor (M5) of the second Drafting unit stage (II) controlled by a common frequency converter (79) becomes.

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