DE4113565A1 - Drawing unit monitor esp. useful for mfg. synthetic yarns - has sensor for at least one electromotor for drafting force to be calculated from slip and or pole wheel angle - Google Patents

Abstract

To monitor the drafting force exerted by the drawing unit for spinners, a sensor (3) registers the rotation of at least one electro-motor (1) where the sliver is drawn between two separate rotation units with their own motors. The difference in the frequency and/or phase between the sensor signal (120) and the nominal frequency signal (110) at the associated frequency converter (2) is established to give the slip and/or the pole wheel angle of the electro-motor to provide the drawing force exerted. Pref. the pole wheel angle or the slip or the calculated drafting force is used as a control value for the electro-motor (1) supplied by a frequency converter, and the drawing action is stopped if the drafting force lies outside preset tolerances, and a signal is generated if the measurements are above or below the nominal value. For test purposes, the drawing unit is operated without material and a signal is generated if the measured parameters are exceeded and, if within limits, the theoretical drafting force is used as a reference value when working with sliver material. The running time of the drafting force, while the spinner is operating, is set to monitor the drawing operation. ADVANTAGE - Pref. the method gives a simple and accurate measurement of the drafting forces at the drawing unit.

Description

The invention relates to a method for monitoring the Ver tensile force in drafting systems of spinning machines with the Merk paint the preamble of claim 1 and a front direction to carry out the procedure.

An essential process step in the production of yarn, stretching is especially synthetic yarns. At this process the material under controlled conditions gen applied with an axial force, whereby the cross cut of the material to be stretched reduced. The for this necessary device has in most cases two with under different speeds rotating elements such. B. Delivery cylinders, godets or winding devices, between which the material to be stretched is guided. When ver Stretching of textile yarns is an essential process parameter the delay to be noted, which results from the ratio of the Discharge speed to the feed speed of the material results.

In the production of synthetic yarns, it is also very important to adhere to the target warping forces specified within narrow limits, since even the slightest irregularities (deviations ± 10 ^-4 target warping force) can change the subsequent fabric properties.

The drive of the rotating elements of such a stretch work is increasingly done by frequency-fed Elek tromotor. The motors can either be central driven with downstream mechanical distribution or as  Single drive with upstream electrical distribution be educated. The control of each individual motor with a separate frequency converter is conceivable.

Because of their inherent property, feed frequency syn to rotate in chronological order find mainly synchronous and reluctance mo gate use.

To monitor the drafting forces during stretching in known drafting systems either the power consumption of the corresponding electric motor or monitored by the electromo Torque delivered torque, for example directly at the Ab drive shaft, measured using a suitable torque sensor sen. Such drafting systems are for example from DE-OS 33 15 247 or DE-OS 17 34 234 known.

A disadvantage in the determination of the output from the electric motor Torque from the electrical power consumption of the motor is the associated relatively large inaccuracy. The Be adjustment of the drafting forces with the required high accuracy speed is therefore not guaranteed by this method, ever however, this method is suitable, for example, for detection suddenly and / or correspondingly large torque changes such as when the material breaks occur between the rotating elements of the drafting system.

The direct measurement of the output from an electric motor Torque, for example on the output shaft or on it driven rotating elements of the drafting system, by means of suitable, high-precision torque sensors guaranteed the required accuracy, however, is being implemented complex and therefore associated with high costs.

The invention is therefore based on the object of a method for monitoring the draft in drafting systems of spinning mills to create machines, on the one hand the high accuracy  requirements met and secondly with a correspondingly low level Effort is to be realized. It is also the job of Invention, a device for performing the Invention to create according to the procedure.

The invention solves this problem with the characteristic feature paint claim 1 and claim 8.

The frequency and / or the phase difference at least one between the sensor signal and the rotational movement of the sensor unit detecting the electric motors and the target frequency signal of the associated frequency converter slip and / or the magnet wheel angle of the electric motor is determined and from it by means of a known functional dependency that of the ro tiert driven element determined generated draft. The instantaneous value or the time course of this way certain pulling force can, for example, by means of a ge own display device shown and / or in another Be processed further. For example, the ver stretching process will be stopped as soon as the drafting force Values that are outside a predetermined tolerance range ches lie. In the same way, an operator can call signal are generated. In addition, the on this Way certain rotor angles or the slip or the resulting certain default force as a control variable within a closed its control loop for the control of the converter-fed Electric motor can be used. It can also be used for cheaper Asynchronous machines are used as drafting system drives.

In addition to the advantages already mentioned len by observing the current drafting force the operating state of the driven motor (phase failure, increased Sag friction), the presence of the yarn (thread monitor, Fa denbruchdetektor), the quality of the raw material and the Current state of the heating devices (temperature or Vis of the material to be drawn).  

Further advantageous embodiments of the invention result from the subclaims.

The invention is described below with reference to the drawing illustrated embodiments explained in more detail. In the Show drawing:

Fig. 1 is a schematic block diagram of a first embodiment of the invention;

FIG. 2 shows the exemplary embodiment of the invention according to FIG. 1 with a special sensor for detecting the rotary movement;

Fig. 3 shows the embodiment in Fig. 1 with a motor, wel cher three induction windings for detecting the Drehbe movement and

Fig. 4 shows a further embodiment of the invention.

In Fig. 1, a first embodiment of the invention is Darge, in which an electric motor 1 with the three Phasenspannun gene 100 of the frequency converter 2 is driven. At the same time, the frequency converter 2 generates a nominal frequency signal 110 which is fed to a comparator unit 4 . The frequency of the desired frequency signal 110 is equal to the frequency of a phase voltage 100th The rotational movement of the motor 1 , which is preferably designed as a synchronous motor or reluctance motor, is detected by a sensor unit 3 coupled to the motor. It is not absolutely necessary that the sensor unit 3 is directly coupled to the motor 1 . Rather, the sensor unit 3 can be coupled with any appropriate design of the sensor with any rotating element driven by the motor 1 of the drafting system, not shown. The sensor signal 120 , which contains the frequency and phase position of the rotatingly driven element as information, is also fed to the comparator unit 4 .

The comparator unit 4 , which can be designed, for example, as a PLL arrangement, compares the frequency - and, if necessary - also the phase position of the sensor signal 120 with the desired frequency signal 110 of the converter 2 and indicates a signal proportional to the frequency and / or the phase difference the downstream electronic evaluation unit 5 . The electronic evaluation unit 5 , which may consist, for example, of a correspondingly adapted microprocessor circuit, is connected both to the frequency converter 2 and to a signal unit 17 and to a display unit 18 .

As a further alternative to the comparator unit 4 designed as an analog circuit, the frequency and / or phase difference between the desired frequency signal 110 and the sensor signal 120 can also be determined using known digital methods.

The electronic evaluation unit 5 calculates from the frequency and / or phase difference supplied to it using a stored, theoretically or empirically determined functional dependency the distortion force generated by the rotatingly driven element. Both the instantaneous draft force can be displayed by means of the display unit 18 and the course of the draft force over time can be stored, evaluated or fed to a central computer (not shown) in the sense of a normal operating data acquisition and further processed there.

The simplest evaluation of the signal containing the frequency and / or phase difference is, for example, to trigger an operator call when the signal unit 17 exceeds or falls below a predefined maximum or minimum value. In the event that the values for the draft force leave the predetermined tolerance range, the frequency converter 2 can be controlled by the electronic evaluation unit such that the motor 1 is stopped.

In addition, the electronic evaluation unit 5 can receive a controller which controls the frequency converter 2 as a function of the specific drafting force in such a way that the drafting force generated by the motor 1 or by the rotatingly driven element is kept constant. This in particular creates the possibility to use asynchronous machines within the above-described re gelkreises to drive the drafting system.

As already mentioned above, fluctuations in draft force lead to torque variations, which in turn reluctance and synchronous motors change the current magnet wheel angle, that is to say a change in the phase difference between the signals 120 and 110 , or in the case of asynchronous machines to a change in the slip s, that is to say Change the frequency difference between the signals 120 and 110 lead. In addition to these torque changes due to the variation in the distortion forces actually acting on the material to be stretched or on the rotatingly driven elements, the torque generated by the motor - and thus also the two other parameters mentioned - is influenced by other influences, such as bearing wear, for example. certainly. Thus, by evaluating the phase and / or frequency difference according to the invention, in addition to the actual monitoring of the desired distortion forces, further statements can also be obtained, for example about the operating state of the drive motor, the presence of the yarn, the quality of the raw material and about the temperature of the raw material. For example, a phase failure causes an apparent increase in load and thus a change in the pole wheel angle or the slip, and the asynchronous running of a reluctance machine caused by an overload leads to an unsteady pole wheel angle or to fluctuations in speed.

The operating state of the drive motor can thereby be determined be that, preferably after starting up the spider Reimmaschine this initially without any material to be processed  is operated and that when a predetermined is exceeded Value for the magnet wheel angle or the slip or from it a certain apparent distortion force a signal is generated. In addition, during this test phase the system-related Always present slip or magnet wheel angle or the one from it determined apparent tension as a reference value for the in absolute ver to be determined during the operating phase of the drafting system serve traction (setting the zero point in the calculation the absolute default force).

FIG. 2 essentially shows the block diagram shown in FIG. 1, but the sensor unit 3 is designed in a special way. Here, one or more marks 8 are arranged on the motor shaft 6 , the number of which is an integral multiple of the number of motor pole pairs. The marks 8 formed in a corresponding manner are detected by a mechanical, optical, inductive or capacitive sensor 7 when the shaft 6 of the electric motor 1 is rotating. The sensor 7 delivers a harmonic square wave signal 120 which is fed to a downstream frequency divider 9 with a uniform motor shaft rotation. The frequency divider 9 provides an output signal 130 , the frequency of which is equal to the frequency divided by the number of motor pole pairs. The output signal 130 is fed back to the comparator unit 4 together with the target frequency signal 110 of the frequency converter 2 . The further evaluation takes place as described above.

A disadvantage of this embodiment is the additional wall for the marks arranged on the motor shaft 6 and the additional sensor 7 as well as the insufficient synchronization between the nominal frequency signal 110 and the sensor signal 120 or the frequency-weighted sensor signal 130 , the angle between two being the minimum phase uncertainty on the motor shaft 6 arranged marks 8 remains. The use of both edges of a switching pulse, which is caused by the movement of a mark 8 past the sensor 7 , reduces this problem, but does not fundamentally solve it.

This problem of insufficient synchronization is solved in the embodiment of the invention shown in FIG. 3. In this case, the sensor serves, in addition to the feed windings of the motor, induction windings 10 , 11 , 12 arranged in the motor, which are preferably arranged parallel to the feed windings of the electric motor. The rotating motor rotor induces a speed-synchronous signal in these induction windings. The signal induced in the induction windings 10 , 11 , 12 is fed to a downstream zero crossing switch 13 , 14 , 15 , which generates a pulse at each zero crossing of the induced signal. The digital signals generated in this way are supplied to an OR stage 16 and combined in this way into a single signal. The frequency of this signal is divided in a frequency divider downstream of the OR stage by twice the number of induction windings, in this case by 6. As in the previously described exemplary embodiments, the divided signal is fed to the comparator unit 4 together with the desired frequency signal of the frequency converter 2 . The subsequent evaluation of these two signals is carried out as described above.

FIG. 4 shows an embodiment of the invention, which ensures an even more extensive monitoring of the drafting system. In this case, the speed ratio of two downstream stretching elements, between which the material runs, is directly monitored. As sensors for the detection of the rotational movement of the two downstream motors 1 , similar to the exemplary embodiment described in FIG. 3, an induction winding arranged in the motor is used. The signal induced in this induction winding 10 is in each case fed to a downstream zero-crossing switch 13 . The further processing of this signal is carried out, on the one hand, analogously to the exemplary embodiments described above, each with a frequency divider 9 , a comparator unit 4 , an electronic evaluation unit 5 , a signal unit 17 , a display unit 18 and a frequency converter 2 assigned to each motor 1 .

In addition, the output signals of the two zero-crossing switches 13 are fed to a further electronic evaluation unit 19 , which calculates the speed ratio from the signals supplied to it and / or, if necessary, the delay ratio or the change in the delay ratio using the diameter of the rotatingly driven drafting element . The speed ratio or the delay ratio can be represented by means of a further display unit 20 . In addition, the additional electronic evaluation unit 19 at a speed or delay ratio, which is outside a predetermined tolerance range, control the converter 2 so that one or both electric motors 1 are stopped.

The generation of an operator call means of a further signal unit, not shown, is of course also possible. Likewise, the two electronic evaluation units 5 and / or the electronic evaluation unit 19 can be combined to form a single electronic evaluation unit and thus be assigned to both motors 1 or, if appropriate, also to several or all motors of the drafting system. Likewise, several motors 1 , which should run at the same speed, can be connected to a single converter 2 .

With the inventive method or with the Invention according device can thus be monitored a single or two parameters, namely the sequence difference or the slip or the phase difference or the Polradwinkel, statements about a variety of different Be  drive parameters of a drafting system, in particular for stretching of synthetic yarns.

Claims (24)

1. A method for monitoring the draft in drafting systems of spinning machines, in particular machines for the production of synthetic yarns, in which the material to be drawn is moved from a first rotating element, which is driven by a first frequency converter-fed electric motor, to at least one further, each of a further frequency converter-powered electric motor with a rotating speed driven rotating element and thereby stretched, characterized in that
the rotary movement of at least one of the electric motors ( 1 ) is detected by means of a sensor unit ( 3 ),
that the frequency and / or the phase difference between the sensor signal ( 120 ) and the target frequency signal ( 110 ) of the associated frequency converter ( 2 ) and from this the slip and / or the magnet wheel angle of the electric motor ( 1 ) is determined and
that from the load-dependent slip and / or magnet wheel angle of the electric motor ( 1 ) determined in this way, the warping force generated by the rotatingly driven element is determined by means of a known functional dependency. 2. The method according to claim 1, characterized in that the magnet wheel angle or the slip or the tensile force determined therefrom is used as a control variable for the control of the converter-fed electric motor ( 1 ). 3. The method according to claim 1 or 2, characterized in that at a value for the magnet wheel angle or the slip or the resulting default force, which is outside of a predetermined tolerance zone, the stretching ge stops. 4. The method according to any one of claims 1 to 3, characterized indicates that when a limit is exceeded or fallen below agreed setpoint range for the magnet wheel angle or Slip or the resulting pulling force a signal is produced. 5. The method according to claims 1 to 4, characterized in net that the spinning machine to be monitored at Testzwec ken is operated without material to be processed and that when a predetermined value for the pole is exceeded wheel angle or the slip or the determined from it apparent distortion a signal is generated. 6. The method according to any one of claims 1 to 5, characterized records that the spinning machine to be monitored without processing material is operated and during this Operating phase of the magnet wheel angle or slip is determined and from this an apparent warping force is determined, which as Reference value for calculating the absolute value for the on actual warpage attacking material to be stretched force during the operating phase with the mate to be stretched rial is used. 7. The method according to any one of claims 1 to 6, characterized records that the time course of the draft during the operation of the spinning machine to monitor the ver stretching process is logged.   8. An apparatus for performing the method according to one or more of claims 1 to 7 with a first rotating element which is driven by a first frequency converter-fed electric motor, and at least one wide ren, each of a further frequency converter-fed electric motor at different speeds driven rotating element, characterized in that
a sensor unit ( 3 ) for detecting the rotary movement is arranged on at least one electric motor ( 1 ) fed by the associated frequency converter ( 2 ),
that the signal ( 120 ) of the sensor unit ( 3 ) and the Sollfre frequency signal ( 110 ) of the associated frequency converter ( 2 ) are fed to a comparator unit ( 4 ) which determines the frequency difference and / or the phase difference of the two signals supplied to it and
that the comparator unit ( 4 ) is followed by an electronic evaluation unit ( 5 ) which, from the frequency difference, the slip and / or from the phase difference, the magnet wheel angle of the electric motor ( 1 ) and, by means of a known functional dependency, the distortion force generated by the rotating element determined. 9. The device according to claim 8, characterized in that the sensor unit ( 3 ) consists of a mechanical, optical, induc tive or capacitive sensor ( 7 ), which the rotational movement of the shaft ( 6 ) of the electric motor ( 1 ) or an associated Partially detected by detecting at least one on the shaft or the associated part attached mark ( 8 ). 10. The device according to claim 9, characterized in that the number of marks is equal to the number of motor poles.   11. The device according to claim 9, characterized in that the number of marks ( 8 ) is an integer multiple (p) of the number of motor pole pairs and that between the sensor ( 7 ) and the downstream comparator unit ( 4 ) a frequency divider ( 9 ) is arranged, which divides the frequency of the sensor signal ( 120 ) by the integer multiple (p). 12. The apparatus according to claim 8, characterized in that in the motor ( 1 ) at least one induction winding ( 10 , 11 , 12 ) is arranged and that the signal induced in the induction winding of the comparator unit ( 4 ) is supplied. 13. The apparatus according to claim 12, characterized in that the induction windings ( 10 , 11 , 12 ) parallel to the Spei sewicklungen of the electric motor ( 1 ) are arranged. 14. The apparatus according to claim 12 or 13, characterized in that between the induction winding ( 10 , 11 , 12 ) and the comparator unit ( 4 ) a zero-crossing switch ( 13 , 14 , 15 ) is arranged, which one at each zero crossing of the induced signal Pulse generates that the output signal of the zero crossing switch ( 13 , 14 , 15 ) when using more than one induction winding by means of an OR stage ( 16 ) and that the output signal from the OR stage ( 16 ) the frequency divider ( 9th ) is supplied, which divides the frequency of the signal fed to it by the number that corresponds to twice the number of induction windings. 15. The device according to one or more of claims 8 to 14, characterized in that the electronic evaluation unit ( 5 ) controls the converter ( 2 ) when it falls below a certain threshold so that the electric motor ( 1 ) is stopped. 16. The device according to one or more of claims 8 to 15, characterized in that the electronic evaluation unit ( 5 ) a signal to a downstream signal unit when falling below or exceeding a predetermined range of the setpoint value for the magnet wheel angle or the slip or the distortion force determined therefrom ( 17 ) delivers. 17. The device according to one or more of claims 8 to 16, characterized in that the electronic evaluation unit ( 5 ) displays the instantaneous value of the determined phase or frequency difference or the exceeding of a predetermined tolerance range of these parameters by means of a display unit ( 18 ) connected thereto . 18. The device according to one or more of claims 8 to 17, characterized in that the electronic evaluation unit ( 5 ) logs and / or stores the time profile of the determined phases or frequency difference. 19. The device according to one or more of claims 8 to 18, characterized in that the electronic evaluation unit ( 5 ) uses the time course of the phase or frequency difference as a decision criterion for stopping the electric motor. 20. The device according to one or more of claims 8 to 19, characterized in that the electronic evaluation unit ( 5 ) uses the temporal course of the phase or frequency difference as a decision criterion for activating a signal unit ( 17 ). 21. The device according to one or more of claims 8 to 20, characterized in that a further electronic evaluation unit ( 19 ) is present which determines the ratio of the speeds of two electric motors ( 1 ) and thus the stretching ratio of a step of a stretching point and optionally by means of a connected display unit ( 20 ) displays. 22. The apparatus according to claim 21, characterized in that the electronic evaluation unit ( 19 ) logs and / or stores the temporal course of the speed ratio or the stretching ratio. 23. The apparatus of claim 21 or 22, characterized in that the electronic evaluation unit ( 19 ) uses the temporal chen course of the speed ratio or the stretching ratio as a decision criterion for stopping one or more electric motors. 24. The device according to one or more of claims 8 to 23, characterized in that the electronic evaluation units ( 5 ) and ( 19 ) are assigned to one or more motors of the spinning machine.