EP0466049A1 - Drive for a drafting machine - Google Patents

Abstract

A drafting machine is driven by means of a plurality of drive motors (7) of regulated position. For this, the motors (7) each have an individual control circuit (8a-8d). According to this invention, each such control circuit will comprise a position sensor (8.1, 8.2, 36) which can also additionally supply a position signal when the motor shaft does not rotate. <IMAGE>

Description

This invention relates to a drafting system drive for textile machines. The invention is particularly in connection with drafting systems in the so-called front mill of a spinning mill, e.g. advantageous in draw frames or in combing machines.

State of the art

It has been known for a long time, particularly in so-called regulating sections, to compensate for mass fluctuations in a (later to be spun) sliver by the controlled change in the draft in a drafting system.

In this context, it is also known that the most difficult problems of the method arise when starting and braking the drafting system. With continuously increasing delivery speeds (with increasing productivity) of the applicable machines, the importance of these start-up and start-up problems increases. At a normal delivery speed of 800 m / min. the run-up or braking period for a distance takes about 1 to 3 seconds. If a defective belt is formed in such a period due to problems in the control loop, these errors can have an effect on the subsequent spinning of a fine yarn with a yarn length of approx. 700 to 2000 m.

The sliver treated in the line must be deposited in a so-called can for transport between processing stages. Usually, the distance for the can change after filling from a can has to be switched off briefly, which requires a braking period and a subsequent start-up period.

DE-OS 2 650 287 has identified the problems of the ramp-up or braking time. However, the solution proposed therein deals exclusively with the transition from run-up to normal operation or from normal operation to braking. It has been assumed that the delay can be kept constant during the run-up or braking phase.

EP 38 927 has recognized that the delay must continue to be regulated even during the run-up or braking phase. However, the "inertia" of the control loop when starting and braking would have to be increased in order to overcome control problems. This solution alleviates the effects of the overall problem without eliminating them.

EP 141 505 also deals with these problems. The proposed solution indicates that in the "worst" area (namely just before and after standstill) the drive system should be brought to a start or standstill "suddenly".

It is also known to individually drive the cylinders of a drafting system by position-controlled motors (EP 355 557). The expansion of this concept for driving a route is also shown in our earlier Swiss patent application No. 2834/89 dated July 31, 1989.

It is the object of this invention to further develop the latter concept in such a way that the behavior of the drive system up to and from standstill can be specified.

The invention provides a drafting system drive with a position-controlled motor, and is characterized in that the control circuit for regulating the motor comprises a position sensor which can deliver a signal corresponding to the angular position of the armature even when the motor armature is at a standstill.

The control loop can also include an evaluation for the position signal, which can derive a speed-dependent signal from changes in the position signal. The invention can also be used when only one drive motor is present and, under these circumstances, it enables this motor to be started or braked very precisely. However, the invention is particularly advantageous where two or more drive motors are present, each motor having its own control loop. In such an arrangement, the mutual behavior of the speeds of the regulated motors can also be precisely determined up to or from standstill.

The position sensor is preferably an electromagnetic sensor. This sensor can comprise a means for generating an electromagnetic field, this field having a preferred direction in space. This field generator is preferably mounted on the motor shaft or connected to the motor armature, so that the angular position of the preferred field direction changes when the motor arm is rotated about the longitudinal axis of the armature. The position sensor can then have a plurality of field sensors, which are distributed around the motor shaft and react to the rotating field with a predetermined phase shift. The field can preferably be excited by alternating current, so that a position signal can be obtained from the field sensors even when the armature is at a standstill.

The position sensor preferably continuously delivers a position signal (analog signal) when the field is excited, a quasi-continuous position signal (with such a high sampling frequency that the evaluation is not influenced by the discontinuities in the position signal) would also be useful. Nevertheless, the evaluation is preferably based on digital technology, so that an analog-to-digital converter is provided between the position sensor and the evaluation that should. The sampling rate of the converter should be chosen in relation to the delivery speed and the properties of the fiber sliver to be drawn in such a way that no control problems (eg vibrations) arise in the existing control loops. The optimal sampling rate can only be determined depending on the desired operating conditions, but a sampling frequency higher than 2500 Hz will normally be required.

• Fig. 1 zeigt schematisch ein Antriebssystem für eine Strecke nach unserer schweizerischen Patentanmeldung Nr. 2834/89 vom 31.07.1989,
• Fig. 2 zeigt eine Uebersicht über die Antriebsanordnung und den entsprechenden Reglern einer Strecke nach Fig. 1,
• Fig. 3 zeigt schematisch ein Positionssensor für einen Regelkreis nach dieser Erfindung,
• Fig. 4 zeigt schematisch den Regelkreis mit einem Sensor nach Fig. 3,
• Fig. 5 zeigt Hochlauf- bzw. Bremskurven für eine Strecke nach dieser Erfindung, und
• Fig. 6 ist ein Diagramm zur Erklärung der Anforderungen an der Auswertung eines Regelkreises nach dieser Erfindung.

The invention will now be explained in more detail with reference to the figures in the drawings, the drive concept according to an earlier Swiss patent application being explained for the sake of completeness with reference to FIGS. 1 and 2.

• 1 schematically shows a drive system for a line according to our Swiss patent application No. 2834/89 from July 31, 1989,
• 2 shows an overview of the drive arrangement and the corresponding controllers of a route according to FIG. 1,
• 3 schematically shows a position sensor for a control loop according to this invention,
• 4 schematically shows the control loop with a sensor according to FIG. 3,
• 5 shows run-up or braking curves for a route according to this invention, and
• 6 is a diagram for explaining the requirements for evaluating a control loop according to this invention.

Fig. 1 shows a schematic representation of an embodiment of the route. In our Swiss patent application No. 4754/88 we show the use of a controlled drafting system in a comber. The principles and systems described below can be used in the comber as well as in the draw frame.

In the system according to FIG. 1, several slivers 15.1-15.6, in the example six of them, are combined side by side to form a loose fleece and are guided through several roller systems 1-6. Due to the fact that the circumferential speed of the rollers increases in two stages in the direction of transport of the fiber material, this is pre-drawn over the first stage (pre-drafting) and further drawn over the second to the desired cross-section (main drafting).

The fleece 18 emerging from the route is thinner than the fleece of the fed strips 15.1 - 15.6 and correspondingly longer. Because the warping processes can be regulated depending on the cross-section of the fed strips, the strips or fleece are evened out as they pass through the line, i.e. the cross-section of the emerging fleece is more uniform than the cross-section of the fed fleece or strips . The present route has a pre-drafting area 11 and a main drafting area 12. Of course, the invention can also be used in an analogous manner in connection with routes with only one or more than two delay areas.

The belts 15.1 - 15.6 are fed into the line by two systems 1 and 2 of conveyor rollers. A first system 1 consists, for example, of two rollers 1.1 and 1.2, between which the fed belts 15.1 - 15.6, which are combined to form a loose fleece, are transported. In the transport direction of the belts follows a roller system 2, which here consists of an active conveyor roller 2.1 and two passive conveyor rollers 2.2, 2.3. During the feed through the roller systems 1 and 2, the fed tapes 15.1 - 15.6 are brought together to form a fleece 16. The peripheral speeds _V1 and v ₂ (= v; _n ) of all rollers of the two roller systems 1 and 2 of the feed are of the same size, so that the thickness of the fleece 16 essentially corresponds to the thickness of the fed strips 15.1-15.6.

The two roller systems 1 and 2 of the feed are followed in the transport direction of the nonwoven 16 by a third system 3 of pre-drawing rollers 3.1 and 3.2, between which the nonwoven is transported on. The peripheral speed _{V3 of} the pre-drafting rollers is higher than that of the infeed rollers _V1 , ₂ , so that the fleece 16 is stretched in the pre-drafting area 11 between the infeed rollers 2 and the pre-drafting rollers 3, its cross section being reduced. At the same time, a pre-warped fleece 17 is created from the loose fleece 16 of the fed-in belts 17. The pre-drafting rollers 3 are followed by a further system 4 of an active conveying roller 4.1 and two passive conveying rollers 4.2, 4.3 for further transport of the fleece. The peripheral speed _{V4 of} the conveyor rollers 4 for further transport is the same as _{V3 of} the pre-drawing rollers 3.

The roller system for further transport 4 is followed by a fifth system 5 of main drafting rollers 5.1 and 5.2 in the transport direction of the fleece 17. The main drafting rollers in turn have a higher surface speed _V5 than the preceding transport rollers, so that the pre-drawn fleece 17 is further drawn between the transport rollers 4 and the main drafting rollers 5 in the main drafting area 12 to the finished drawn fleece 18. the fleece 18 is brought together into a band via a funnel T.

Between a pair 6 of outlet rollers 6.1, 6.2, the circumferential speed v6 ( ⁼ V _ou t) of which is the same as that of the preceding main drafting rollers (vs), the finished stretched belt 18 is led away from the line and placed in rotating cans 13.

The roller systems 1, 2 and 4 are driven by a first servo motor 7.1, preferably via toothed belts. The pre-drawing rollers 3 are mechanically coupled to the roller system 4, wherein the translation can be adjustable or a target value can be specified. The gear (not visible in the figure) determines the ratio of the peripheral speeds of the inlet rollers (v; _n ) and the peripheral speed _{V3 of} the pre-drafting rollers 3.1, 3.2, hence the pre-drafting ratio.

The roller systems 5 and 6 are in turn driven by a servo motor 7.2. The inlet rollers 1.1, 1.2 can also be driven by the first servo motor 7.1 or optionally by an independent motor 7.3. The two servomotors 7.1 and 7.2 each have their own controller 8.1 and 8.2. The regulation takes place via a closed control loop 8.a, 8.b or 8.c, 8.d. In addition, the actual value of one servo motor can be transmitted to the other servo motor in one or both directions via a control connection 8.e so that everyone can react accordingly to deviations from the other.

The mass or a quantity proportional to the mass, e.g. the cross section of the fed strips 15.1 - 15.6 measured by an inlet measuring element 9.1. At the exit of the line, the cross section of the emerging strip 16 is then measured by an outlet measuring element 9.2.

A central computer unit 10 transmits an initial setting of the target size for the first drive via 10.a to the first controller 8.1. The measured variables of the two measuring elements 9.1, 9.2 are continuously transmitted to the central computer unit via the connections 9.a and 9.b during the stretching process. From these measurement results and from the setpoint for the cross section of the emerging belt 18, the setpoint for the servo motor 8.2 is determined in the central computer unit and any other elements. This setpoint is continuously given to the second controller 8.2 via 10.b. With the help of this control system (the "main control"), fluctuations in the cross-section of the fed strips 15.1 - 15.6 can be compensated for by appropriate control of the main drafting process or the strip can be made more uniform.

The drive concept of an arrangement according to FIG. 1 with its regulation is explained in more detail with reference to FIG. 2. In the present case, the two servomotors 7.1 and 7.2 serve as the main drive. The servo motor 7.1 drives the roller system 1 of the inlet and the system 4 of conveyor rollers, the latter following the advance section. The pair of pre-drawing rollers 3 is mechanically coupled to the roller system 4 and is therefore also driven by the servo motor 7.1. The roller pair 1 at the inlet is either driven by the servo motor 7.1 via an intermediate drive 7.3 (gear) or, in another embodiment variant of the line drive, can be driven by an independent servo motor 7.3. The servo motor 7.2 drives the pair of main drafting rollers 5 directly. The funnel wheel pair 6 is also driven by the servo motor 7.2 via a gear 7.4. The can 13 is driven at the outlet of the drafting system either via an intermediate drive 7.5 (gearbox) driven by the servo motor 7.2 or, in another embodiment variant of the drafting system, by means of an independent drive motor 7.5.

The drive concept is based on the fact that at least one drive group within the route is driven independently by a regulated motor. A controlled motor can be provided for each independent drive group of a warping area or, if required, also a conveyor or transport section or other process-linked work stations; in the example shown, there are two of them, namely the motors 7.1, 7.2 of the pre-drafting area 11 and the main drafting area 12. Basically, faults caused by the drives can be compensated for as part of the overall system control, i.e. the main control. However, it proves advantageous to control each drive group individually, i.e. to provide a meshed control with corresponding controllers 8.1, 8.2. Of particular importance is the fact that the system deviations that occur in the overall system are influenced in an advantageous manner and that better time dependencies are created, or any disruptions are precompensated. Such auxiliary units controlled by means of controllers 8.1, 8.2 can be used in various main control concepts.

The drive of the drafting system is regulated on two levels, a superordinate main control 9.a, 9.b, 10.a, 10.b, in which the central computer unit 10 takes on an essential function, and at least one subordinate auxiliary control 8.2 for the main delay area. In the present case, two controllers 8.1 and 8.2 are provided for the auxiliary control of both the main delay area (including the run-out area) and the advance area (including the lead-in area). In the design variants already mentioned, all due additional controllers 8.3, 8.5 are provided, which are shown here in dashed lines. Position controllers are preferably used in connection with the two servomotors, which can be designed, for example, as brushless DC motors. The meshed control with a main and at least one auxiliary control relieves the load on the central computer unit 10 and reduces the risk of large strokes occurring in the main control.

The main control system 9.a, 9.b, 10.a, 10.b delivers setpoints, for example speed setpoints, via 10.a or 10.b to the main drive motors 7.1 or 7.2, which consist of the set cross-section of the emerging belt and the measured actual cross-sections of the fed-in belt or the fed-in belts 9.a and the emerging belt 9.b are calculated. Depending on the configuration of the control, further parameters can be taken into account.

The speeds of the individual drive motors 7.1 and 7.2 (for the design variants also 7.3 and 7.5) are set in closed position control loops 8.a, 8.b and 8.c, 8.d (in the design variants) by means of auxiliary controls 8.a - 8.k. also 8.f, 8.g and 8.i, 8.j) regulated to the target values required by the upper regulation level. Differences between the actual and target values of the motor speeds are transmitted between the position controllers 8.1, 8.2 via a control connection 8.e (possibly also 8.k and 8.h). It can be provided that a deviation outside the control range of the relevant controller 8.1 and 8.2 (possibly also 8.3 or 8.5) between the setpoint and actual value of the speed of the motor in question and the position controllers of the other motors can be compensated for by appropriate corrections in the setpoints for the speeds of the other motors. In this case, corresponding returns to the central computer unit 10 can be provided. In a preferred embodiment, this correction takes place internally in the corresponding controllers.

The drive motors, which determine the distortion, each form a position-controlled drive system with their respective control loops. For this purpose, each motor can be provided with an encoder or a resolver, which gives the angular position of the drive shaft to the position control for this motor at any time with predetermined accuracy as an actual value. The control of the drafting system can be mutually coordinated via these position control loops, the angular positions of the motor shafts and thus the rollers of the drafting system driven by them.

Such a drive system enables much better warping accuracy than can be achieved with speed-controlled motors. At the same time, the use of position controllers according to the present invention as an auxiliary controller (not a speed controller) has the advantage that the controller is guaranteed even when the motor is at a standstill. There are advantages when starting up or running down the line, since much better control accuracy is possible at low speeds until standstill.

Position regulators according to the present invention are used as regulators in the context of the auxiliary regulation, since these ensure regulation even when the motor is at a standstill. The corresponding controllers 8.1, 8.2 (or any other controllers within the scope of the embodiment variants) can contain separate computer units (for example with digital signal processors or microprocessors) or can also be designed as a module of the central computer unit 10.

The drive concept therefore assumes that independent drive units or groups of the route are controlled separately. A drive group is understood to mean a unit that contains at least one motor, including the rollers or guide or transport rollers driven by it. Such a drive group represents, for example, in the exemplary embodiment according to FIG. 2, the group 7.2, 7.4, 7.5, 5 and 6 containing the motor 7.2. A preferred embodiment of the route provides a digital synchronization control of the drive groups for the nominal settings. A drive group serves as the master drive. The control of a drive group can then be achieved by changing the nominal setting.

This makes it possible that from the overall control system only the setpoint for the manipulated variable, i.e. to specify the value or a correction quantity for the delay. In addition, it must be taken into account that the main control should compensate for both short-term and slow faults. The drive system shown enables meshed control and thus uses the improved time dependency. The control connections 8.e, 8.h, 8.k also enable shorter system response times. Divergences in the drive systems do not have to be detected via a closed main control loop with a corresponding dead time.

Such a separate regulation of each drive group also has significant advantages, in particular when several warpage regions are provided, of which, however, only or a part of or should be regulated. Those areas with constant warping can be operated by simply specifying the setpoint, without the need for regulation by the main regulation.

The rule shown in Figures 1 and 2 principle guarantees a very good leveling even if unforeseen changes in the operating conditions. Both short-term disturbances and slow changes can be optimally compensated within the scope of this regulation. The manipulated variable determined by a main control, here for example for the main delay, serves as an input variable for the corresponding controller 8.2.

Figure 3 shows schematically a position sensor for use in the closed control loops 8a, 8b, and 8c, 8d of Figures 1 and 2. The reference number 30 indicates the armature e.g. from the engine 7.1 (Figure 1). With suitable current excitation of the stator windings (not shown) of the motor, the armature 30 rotates about its own longitudinal axis 32. The armature 30 is connected to a shaft 34 which carries a field-generating element 36. The element 36 comprises two "shoes" 38, 40 made of a ferromagnetic material (e.g. steel) or a material with corresponding field-influencing properties. The shoe 38 is mounted directly on the shaft 34, while the shoe 40 is carried by the shoe 38 via an intermediate piece (bolt) 42.

A conductor 44 for electrical current lies with a few turns 46 on the intermediate piece 42. When current is applied to the conductor 44 from a suitable source 48, an electromagnetic field is generated in the intermediate piece 42, which is then influenced by the shoes, in order to avoid that in the adjoining room to design the resulting field in a predetermined manner.

The electromagnetic field generated by the turns 46 in the bolt 42 is rotationally symmetrical. At the transition from the bolt 42 to the shoes 38, 40, the rotational symmetry is eliminated by the shape of the shoes. Each shoe 38, 40 is namely a flat element with a depth t which is substantially smaller than the axial length 1 or the width b of the element. The effect of this flat shape of the shoes 38, 40 is that when the bolt 42 in the shoes transitions, the electromagnetic field preferably propagates in directions that lie within these shoes. This means that the field has preferred directions, which are indicated schematically by the arrows X in FIG. 3. These directions are preferred in the sense that when the shoes 38, 40 are rotated about the longitudinal axis 32 of the armature 30, the electromagnetic coupling with a field-sensitive element is much stronger in the X directions than in the Y directions perpendicular to the X directions.

Each shoe 38, 40 has two surfaces 50 (only one surface 50 per shoe visible in FIG. 3), which are directed radially outwards. When the armature 30 (and therefore the shoes 38, 40) is rotated about the axis 32, each pair of surfaces 50 describes a circular cylinder, which is referred to below as the "jacket". Two field-sensitive elements 52, 54 connect to the jacket of the shoes 38, 40 as close as possible. Each element 52, 54 has two shoes 39, 41 and a connecting rod 56. Each shoe 39 has a surface 58 which corresponds in shape and dimensions to the surfaces 50 of the shoe 38 and which is as close as possible to the jacket of the shoe 38. In a similar manner, each shoe 41 has a surface 60 which corresponds in shape and dimensions to the surfaces of the shoe 40 and which is as close as possible to the jacket of the shoe 40. The surfaces 58, 60 of the element 52 are perpendicular to the surfaces 58, 60 of the element 54. This means that the electromagnetic coupling between the shoes 38, 40 and the element 52 reaches a maximum strength at the point in time when the electromagnetic coupling between the shoes 38, 40 and the element 54 have a minimum thickness.

Around the connecting rods 56 of the elements 52, 54 there are turns 62 of respective signal conductors 64, which forward the output signals from the field-sensitive elements to the evaluation. The signal strength in conductor 64 from element 52 therefore reaches a low point at the same time as the signal strength in conductor 64 from element 54 and vice versa.

• A = sin sin wt
• B = cos sin wt

wo A und B die beiden Ausgangssingalkomponenten, ein Mass für die Winkelstellung der Schuhen darstellt und wt die konventionellen Kenngrössen für eine sinusförmige Welle sind.Now assume that source 48 generates an AC voltage with a sinusoidal waveform. The alternating current in the turns 46 generates an electromagnetic field in the bolt 42 and in the shoes 38, 40. The electromagnetic field is coupled to both output lines 64 via the two pairs of shoes 39, 41, so that the input signal coming from the source 48 excites an output signal which consists of two components, namely a component in the conductor 64 of the element 52 and a second component in the Conductor 64 of element 54. The signal strength of these two components is not only a function of time (depending on the input signal generated in source 48) but is also a function of the angular position of shoes 38, 40 about axis 32, specifically after relationships

• A = sin sin wt
• B = cos sin wt

where A and B are the two output signal components, a measure of the angular position of the shoes and wt are the conventional parameters for a sinusoidal wave.

Because both components A, B of the output signal are directly dependent on the input signal, it is possible in a suitable evaluation of the Filter out the influence of the input signal and obtain a signal which is a function of only the angular position of the shoes 38, 40. However, because the carrier wave (the input signal generated by the source 48) is time-variable, the two components A, B of the output signal arise in the conductors 64 even when the armature 30 (and therefore the shoes 38, 40) stand still. This means that the angular position (the position) of the shoes 38, 40 can also be derived from the evaluation if the motor is not excited with the armature 30.

If the position of an object can be determined at any time and can be represented by a suitable signal, it is possible to derive the speed (in the case of a rotary movement, the speed) of the movement by changing this position by forming a differential function. This derivation can also take place in the evaluation, which is now to be described in rough outline with reference to FIG. 4.

4 again shows the motor 7.1 and schematically the sensor 36 with the connecting shaft 34 and the two output lines 64. These two lines each give their signal components to an input from a microprocessor 70. This processor receives a further input signal from the central controller 10 (see also Fig. 1) and passes a control signal to a motor controller 72. The engine controller 72 uses the latter signal to determine the power made available to the engine 7.1.

The operations performed in the microprocessor 70 are determined by the programming of the processor. To explain these operations, however, the main steps are shown graphically in FIG. 4A as "hardware elements". Accordingly, the two signal components emitted by the sensor 36 are first converted into respective digital signals by an analog / digital converter A / D and passed on to a divider 74. The divider 74 forms, for example, the quantity tan 4) and forwards the corresponding signal to a comparator 76. This instantaneous (actual) value for the angular position of the shoes 38, 40 is compared in the comparator 76 with a target value, which is available in a suitable memory 78. Any difference (deviation) between the setpoint and actual value is represented by the comparator 76 in the form of a deviation signal and is output to the engine controller 72 for controlling the engine output.

The setpoint value in the memory 78 can be changed depending on the programming, specifically depending on a sequence program defined in the central control 10 and on the machine settings entered in the central control 10. An example of a sequence program has been shown schematically in FIGS. 5 and 6.

5 shows the run-up 80 from standstill at a constant operating speed N and the subsequent braking 82 to standstill. Normal operation is largely cut out of the diagram, since this state has no meaning in connection with FIG. 5. The relevant considerations are described below in connection with the run-up 80, and they also apply in connection with the braking 82.

A start-up curve with a controlled transition 84 from standstill, a central part of constant steepness (constant acceleration) and a controlled transition 86 into the operating speed N is desired. The constant steepness of the central part of this characteristic and the controlled transition 86 into the operating speed N are also present today no particular problems for systems according to the prior art. Problems arise at transition 84 from standstill. In this context, it is not sufficient to provide a position control for the drive motor if the generation of an output signal from the position sensor of this control is dependent on a rotary movement of the motor armature. It is then practically impossible to track the "position" of the anchor exactly at a standstill. The sensor 36 shown schematically in FIG. 3, however, is not dependent on a relative movement of the shoes 38, 40 with respect to the field-sensitive elements 52, 54 in order to generate an output signal. This sensor delivers a position signal even when the motor armature 30 is stationary. A speed-dependent signal can be derived from the corresponding changes in the output signal from the sensor 36 even at the lowest speeds of the armature 30.

The invention therefore enables the precise regulation of the motor speed during starting and braking and offers corresponding advantages, even if only one motor is present. However, the invention is particularly advantageous where there are two or more motors (see FIG. 1) and an exact speed ratio between these motors is to be maintained in all operating states, i.e. also during common start-up and braking phases. This is known to be the case in connection with drafting systems.

In Fig. 5 it was assumed that it was only necessary to understand a preprogrammed running characteristic. In practice, this is the case for a drive group (roller group) that runs at a constant speed in normal operation. In a regulating system, however, the speed of at least one drive group must also be reached after the programmed speed N has been reached be changeable in order to compensate for fluctuations in mass in the processed sliver due to warpage changes. This is indicated schematically in FIG. 6, for the sake of simplicity a sinusoidal change (dashed line) in the speed of the relevant drive group by the operating speed N is assumed. A regulating section that can be used at delivery speeds of at least 800 m / min. Also to compensate for short-wave mass fluctuations, sinusoidal speed changes (as shown in dashed lines in FIG. 6) with a period of a maximum of three msec. can execute. In order to ensure this by a closed control circuit according to FIG. 4, the sampling rate of the A / D converter should be at least 3 kHz, so that each cycle Z (FIG. 6) is sampled at least ten times by an (imaginary) sinusoidal speed change and with one corresponding target value can be compared.

An arrangement according to Fig. 3 gives a position signal which corresponds to the angular position of any radius on the motor armature (e.g. of the radius R, Fig. 3) with an uncertainty ± 180, i.e. on the basis of a position signal from the sensor 36, it is not possible to determine whether the radius R is in the position shown or in a diametrically opposite position. The distinction between these two options is not necessary for use in a draft control. If, however, it appears to be necessary in a particular case, a suitable signal can be obtained by appropriately designing the field generator (shoes 38, 40) and adapting the field-sensitive elements 52, 54, which signals both the direction and the angular position of a reference vector indicates on the motor anchor.

Claims (9)

1. A drafting system drive with a controlled motor (7.1), characterized in that the control circuit (36, 70, 72) for the motor (7.1) comprises a position sensor (36) which also delivers a position signal when the motor armature (30) is at a standstill can, which corresponds to the angular position of the armature (30). 2. Drafting system drive according to claim 1, characterized in that the position sensor (36) comprises means (38, 40 for transmitting electromagnetic energy from a field-generating system (42, 46) to a field-sensitive system (52, 54, 56, 62). 3. drafting system drive according to claim 2, characterized in that the field-sensitive system (52,54,56,62) comprises at least two field-sensitive elements (52,54) distributed around the axis of rotation of the armature. 4. drafting system drive according to one of the preceding claims, characterized in that an evaluation (70) is present in order to derive a speed-dependent signal from changes in the position signal. 5. drafting system drive according to claim 4, characterized in that the evaluation (70) is designed for processing digital signals and means for converting an analog position signal into a digital position signal are provided. 6. drafting system drive according to claim 5, characterized in that the sampling frequency of the converter is higher than 2500 Hz. 7. drafting system drive according to one of the preceding claims, characterized in that a plurality of drive motors (7.1,7.2) is present, each motor being provided with its own control circuit and with its own position sensor according to claim 1. 8. drafting system drive according to claim 7, characterized in that the individual control loops are connected to a common controller (10) for determining a predetermined mutual sequence. 9. drafting system drive according to claim 7 or 8, characterized in that the drafting system is designed to compensate for fluctuations in mass of the material to be processed.

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