DE1139997B - Method and device for the detection and elimination of faulty, spontaneous changes in cross-section in textile material, in particular in yarns, rovings and tapes - Google Patents

Description

Method and device for the detection and elimination of faulty, spontaneous changes in cross-section in textile material, especially in yarns, rovings and tapes In the textile industry, a number of processes and corresponding ones are used Devices have become known that aim to remove yarn defects before they become noticeable in further processing or only in the finished product. Such yarn defects are in the most common cases as strong local thickenings recognizable.

Known methods and their devices work so that that too testing textile material is scanned by a measuring element. As soon as a yarn fault enters the measuring element, a thread separating element is triggered, which the textile material in the vicinity of the point of failure.

Measuring devices that emit an electrical signal are very common, which represents an image of the respective cross-section of the textile material. These Signals are generally very weak and must therefore be used in amplifier equipment be amplified, which requires the use of tubes.

This has the consequence that the operational safety meets the requirements of Practice does not conform, as such devices are in most cases on strong vibrating machine parts and thus the service life of the tubes is very short.

Attempts are therefore made to make such devices as small as possible Number of tubes to build, which, however, on the one hand the stability of the responsiveness on the other hand, the equality of the sensitivity of several devices mounted on the same machine.

Further disadvantages of the known devices equipped with tubes are the high operating voltages required, which are supplied to the various often poorly accessible measuring points have to be supplied, furthermore the long ones Warm-up times of the devices until the necessary stability of their sensitivity is reached as well as the size of the devices due to the tube dimensions.

Recently, devices for the detection of spontaneous Changes in cross-section in textile material have become known, in which one with transistors equipped simple toggle switch is used when voltage peaks occur to operate a thread separator in the input signal.

Such simple flip-flops, however, do not provide reproducible precisely enough Response sensitivities, because both the evaluation of the output from the measuring element Signal as well as the generation of the necessary for the operation of the thread separator Pulses can be made in one and the same simple flip-flop. Through this the response of this device to impulses will depend on what their shape is not allowed.

In the art, however, circuit types are known which are used to certain voltage states of an electrical signal in a pulse equal To reshape duration (Schmitt trigger), or those in which a certain voltage state of an electrical signal triggers a pulse of specified duration (monostable Multivibrators). However, each of these types of circuit cannot be used on its own to meet the requirements for the task to be solved.

The present invention avoids and relates to these disadvantages first of all, a method for the detection and elimination of faulty spontaneous Changes in cross-section in textile material, especially in yarns, rovings and Ribbons, with the cross-sectional shape of the textile material in electrical measuring devices corresponding electrical signals formed, these signals in transistor-equipped Circuits converted into impulses and for the actuation of impulse-controlled thread separators are used, and according to the invention is characterized in that initially characteristic, solely from spontaneous changes in cross-section of the Textile material caused shapes of the electrical signal -in rectangular pulses with indefinite Time duration are transformed, then these square pulses are differentiated and these differentiated square-wave pulses are converted into pulses with a certain time duration which impulses are finally fed to the thread separating organs.

The invention also includes a device for determining and Elimination of defective, spontaneous cross-section changes in 'textile material, especially in yarns, rovings and ribbons, with measuring devices for the formation of electrical, Signals corresponding to the cross-section of the textile material, with transistor-equipped signals Circuits for converting - the signals into pulses, - with RC elements for differentiation the signals and with pulse-controlled thread separators, - which according to the invention characterized -is- by a Schmitt trigger for the formation of a square pulse when - an input signal arrives, by an RC element for differentiation of the square pulse and a monostable multivibrator to generate a the thread separating element controlling pulse with a certain period of time.

On the basis of the following description and figures are däs Method according to the invention and a device for carrying out this method for example explained. 1 shows a block diagram of a complete device, FIGS. 2a to 2d show the instantaneous voltage values as a function of time at the connection points of the individual circuit groups - the device, Fig. 3 and 4 a complete Scheme of the device, FIG. 5 a detail of the scheme, FIG. 6 a further detail of the scheme.

The block diagram of FIG. 1 shows a measuring element 1 in which the Changes in cross-section of the textile material 10 in a manner known per se, changes in capacitance cause. The measuring element 1 is fed by an HF oscillator 9 with HF voltage. The resulting high-frequency changes in capacity as a result of these changes in capacity Voltage fluctuations are rectified in a demodulator 2 and arrive as an electrical signal ul to a preamplifier 3, where the same is amplified and as Input signal U2 is applied to a Schmitt trigger 4. The Schmitt trigger 4 in turn gives when its characteristic threshold voltage Uk is exceeded Square-wave pulses u3 with the short duration T ab, which differentiate in a CR element 5 and the impulses U4 are a known monostable multivibrator 6 controls. The monostable multivibrator 6 delivers a square pulse, which begins at the same time as the input pulse U4, but its duration T remains constant and is generally greater than the time interval. This square pulse is U5 placed on a pulse power amplifier 7, which is responsible for the control of a Thread separator 8 delivers the required power.

Fig. 2 a to 2d show the at the connection points between the Circuit groups occurring voltages as a function of time and illustrate thus the functioning of the device according to the invention.

In Fig. 2a is the course of the input signal u ¢, which is the cross-sectional course of the textile material 10 is shown. The known Schmitt trigger4 has the property that all voltage fluctuations at its input, its characteristic breakover voltage Uk does not have any effect on its output voltage Have U3.

If, however, the input signal U2 has the characteristic breakover voltage mentioned UL - as shown by the tip 54 - is reached, occurs at the exit Rectangular pulse 55, which lasts until the input signal u2 again below the breakover voltage Uk has dropped. This behavior is illustrated in FIG. 2b.

The time duration r corresponds to the time during which the input signal u2 exceeds the breakover voltage Uk and is therefore not constant. During the exam of textile material to detect incorrect, spontaneous changes in cross-section, which cause such voltage spikes 54 is generally the time T very short. Only in rare cases does it achieve values that are direct and reliable Actuation of an electromagnetic relay are required.

The emitted by the Schmitt trigger 4 square pulse 55 is in a RC element 5 differentiated.

The resulting voltage pulse 56, 57 is illustrated in FIG. 2c. The positive voltage spike 56 of the pulse is used to trigger the downstream monostable multivibrator 6 is used, while the negative voltage spike 57 of the pulse u4 remains without influence.

The monostable multivibrator 6 is said positive Voltage peak 56 of the pulse u to tip over into its unstable operating state excited and remains in the same during a certain time interval T. To When this happens, it switches to the original stable operating state without any external impetus back, as illustrated in FIG. 2d. The time interval T is from time T of the pulse 55 is not dependent and constant.

FIGS. 3 and 4 show a detailed circuit diagram as an exemplary embodiment a device according to the invention. Of course, instead of the in 3 and 4 shown, the high-frequency voltage generating oscillator 9, of the measuring element 1, the demodulator 2, the preamplifier 3, the Schmitt trigger 4, the RC element 5, the monostable multivibrator 6, the power amplifier 7 and of the thread separating element 8, other circuit arrangements can also be used, provided that they serve the same purpose.

The oscillator 9 for feeding the measuring element 1 is for example an inductively coupled high frequency oscillator. A high frequency transistor 95 is received its required operating voltages via the resistors 91, 92, 93 and the Coil 98. Capacitor 94 is used to short-circuit the resistor in terms of high frequency 93. The resonant circuit which determines the oscillator frequency consists of the coil 98 and capacitor 96. The feedback and phase rotation from the collector of the transistor 95 on its basis takes place inductively from coil98 to coil 97. The high-frequency voltage is decoupled via the autotransformer 98, 99.

The measuring element consists of a number of measuring capacitors 11, 12, 13 and 14. The high frequency coming from the high frequency oscillator tension is supplied via a separating capacitor 15.

The demodulator 2 has the diodes 21, 22, 23, 24, charging capacitors27 and 28 as well as resistors 25 and 26. The demodulated signal appears between Terminals 29 and ground.

The preamplifier 3 is designed as a two-stage LF amplifier. The signal ul is passed through a capacitor 37 of the first as a differential amplifier acting amplifier stage supplied. This differential amplifier stage consists of the transistors 31 and 32, the resistors 34, 35 and 36 for setting the operating point and the work resistance 38.

A further amplifier stage is coupled via capacitor 39, consisting of a transistor 33, the resistors 301 and 303 for setting the operating point, the capacitor 302 for decoupling the resistor 301 and the load resistor 304

The amplified signal us is coupled out via capacitor 305. Of the LF amplifier is fed back via resistor 306.

The Schmitt trigger 4 with the shunt 43 above the input consists of two transistors 41 and 42, a working resistor 45, a voltage divider, formed from the resistors 46 and 48, the capacitor 47 and a common Emitter resistor 44. The impulses 55 arising at the working resistor 45 are removed at terminal 49 and the RC element 5, consisting of capacitor 51 and resistor 52, supplied.

The voltage peaks 56, 57 generated in the RC element 5 pass over Terminal 53 on the monostable multivibrator 6. It is made up of the transistors 61 and 62, load resistors 63 and 64, a voltage divider, consisting of the Resistors 66 and 67, and a feedback capacitor 65. The pulse with the Pulse length T is fed to terminal 69 via resistor 68 and appears there as Impulse 58.

Pulse 58 is in the power amplifier 7, consisting of the transistors 71 and 72 in compound circuit and the resistor 73, amplified and connected to terminal 74 guided. The thread separating element 8 with the magnetic coil 81 forms the working impedance for the power amplifier 7. The diode 82 serves to suppress high switching voltage peaks at the moment when the magnetic coil 81 is switched off by the output amplifier 7.

The sensitivity with which the spontaneous changes in cross-section must be recorded in the textile material 0 to be tested, for the following reasons certain limits can be set: 1. To adapt to the yarn number to all to be able to test occurring cross-sections with one and the same measuring element; 2. to Fulfillment of the demand made by practice, spontaneous cross-sectional changes to be recorded as required depending on their size and frequency.

Since, as a rule, a number of devices of the type described are mounted on the same machine and all have the same textile material 10 is submitted for examination, it is advantageous if the sensitivity setting can be centrally controlled for entire groups of devices. A possible The solution to this is that the Amplitude of the high frequency voltage by changing it the DC supply voltage U2 of the high-frequency oscillator common to all devices 9 is varied. In Fig. 5, a high-frequency oscillator 9 is shown, its DC supply voltage U2 is supplied from a variable voltage source 101 via terminal 100.

A second possible solution is that the input signal u2 on Input of the Schmitt trigger 4 a variable DC voltage U4 is applied, which in turn can be set together for all devices. Fig. 6 shows the called Schmitt trigger 4, the shunt 43 being connected to terminal 50 and instead of ground is further led to a central variable DC voltage source 102.

The breakover voltage Uk of the Schmitt trigger 4 has the property that it has a certain instability which - seen in absolute terms - roughly constant is and therefore becomes relatively smaller with increasing breakover voltage Uk. Simultaneously but also reduces the mentioned instability compared to the one at the entrance of the Schmitt trigger 4 lying input signal u2, so that with advantage large Signals2 and consequently large values of the breakover voltage Uk are used. The consequence of this is that the responsiveness to spontaneous changes in cross-section is significant is more stable than when small input signals Ul at low breakover voltages Uk (with relatively greater instability) would be used.

Leave the present method and apparatus can of course also be used in all cases in which the electrical Signal Ul or the input signal u2 by measuring the cross-section of the textile material 10 photoelectrically, by mechanical scanning, by pneumatic means or with the help of radioactivity generated by natural or artificial means is obtained. It is only essential that the electrical signal kl is an approximate one An image of the cross-sectional profile of the textile material 10 to be tested is.

Claims (12)

PATENT CLAIMS: 1. Procedure for the detection and elimination of faulty, spontaneous cross-sectional changes in textile material, especially in Yarns, rovings and ribbons, with the cross-sectional profile in electrical measuring devices of the textile material corresponding electrical signals are formed, these signals in transistor-equipped circuits are converted into pulses and used to operate pulse-controlled ones Thread separators are used, characterized in that initially characteristic, caused exclusively by spontaneous changes in cross-section of the textile material (10) Forms the electrical signal (u2, 54) into square-wave pulses (us, 55) with indefinite Time duration (T) are transformed, then these square-wave pulses (55) are differentiated and these differentiated rectangular pulses (a4, 56) in pulses (Us, 58) with a certain period of time (D are converted, which pulses (58) finally the Thread separators (8) are fed. 2. The method according to claim l, characterized in that the electrical Signal (ul) is amplified to such an extent that the spontaneous, faulty Changes in cross-section in the textile material (10) caused stress peaks (54) of the input signal (U2) the breakover voltage (Uk) of the Schmitt trigger (4) at least reach. 3. The method according to claims 1 and 2, characterized in that that the breakover voltage (Ue) of the Schmitt trigger (4) is set so high that the the instability of the breakover voltage (Uk) inherent in the Schmitt trigger relative to Input signal (u2) becomes small and consequently does not interfere. 4. The method according to claims 1 to 3, characterized in that that the input signal (u2) at the input of the Schmitt trigger (4) is a variable DC voltage (U4) is pressed in such a way that the sensitivity to spontaneous changes in cross-section is made adjustable in the textile material (10). 5. Direction for the detection and elimination of faulty, spontaneous changes in cross-section in textile material, especially in yarns, rovings and tapes, with measuring elements for the formation of electrical, the cross-sectional shape of the Textile material corresponding signals, with transistor-equipped circuits for Conversion of the signals into pulses, with RC elements to differentiate the signals and with impulse-controlled thread separators, characterized by a Schmitt trigger (4) to form a square pulse (55, U3) when an input signal arrives (U2), by an RC element (5) for differentiating the square pulse (55, U3) and by a monostable multivibrator (6) to generate the thread separating element controlling pulse (58, us) with a certain duration (D. 6. Apparatus according to claim 5, characterized by a bridge circuit to obtain the electrical input signal (um). 7. Device according to claims 5 and 6, characterized by a high-frequency oscillator (9) for feeding said bridge circuit. 8. Device according to claims 5 to 7, characterized by a high-frequency oscillator (9), the amplitude of which is the high-frequency voltage it emits is adjustable. 9. Device according to claims 5 to 8, characterized by a variable DC voltage source (101) for feeding the in its amplitude adjustable high-frequency oscillator (9). 10. Apparatus according to claim 5, characterized by a measuring capacitor combination (1) with at least one measuring capacitor, through which measuring capacitor combination the textile material to be tested (, 0) is passed through. 11. The device according to claim 5, characterized by a photoelectric Arrangement for obtaining the electrical input signal (U2). 12. The device according to claim 5, characterized by a variable DC voltage source (102) for supplying a variable bias voltage (U4), the the input signal (U2) is pressed. Publications considered: Swiss patents No. 169,327 327774; French Patent No. 1181,422; "Journal of Scientific Instruments «, 1938, issue 1, pp. 24 to 26.