DE1961207C3 - Thread monitor - Google Patents

Description

ίο The invention relates to a thread monitor, which responds to bead-like thread thickenings in a warp belt, which extends through a plane moves a beam of light through it which impinges on a photodetector which provides an output signal generated, the amplitude of which is a function of the brightness of the incident light beam and which one electronic evaluation circuit can be fed, which one, two or three for certain error sizes has adjustable and addressable circuits, each of which has an amplifier and via the outputs of which a switch-off relay can be controlled to switch off the warping belt.

The feeding of a large number of threads in the form of a warp belt is carried out in numerous different ways Applied devices for processing yarns or threads, z. B. also for knitting machines, in particular tricot or warp knitting machines, also in weaving machines or looms, when feeding the threads from a creel to a warp building machine or to the warp beams of warp knitting machines and in similar apparatus for making yarn used in the textile industry and other textile products. An instant detection of imperfections in the warp forming threads, e.g. B. of thread beads and the like or of thread breaks in a number of The web of endless thread composing it is of particular importance for several reasons as it is Only in this way is possible to avoid costly losses such as those involved in making a faulty one Goods are created with the help of a knitting machine or a 'loom to which the warp belt is fed will.

Known thread monitors of the type mentioned (British patent specification 9 96 181) usually meet three different tasks. They make it possible to detect larger errors and a cut-off relay for To operate the processing machines, they detect minor errors and count them without them Stopping textile machines and they determine the length of a long flaw or a series of flaws. Here, the circuits or channels are used to detect larger or smaller errors on the formed the same way and the only difference is in the setting of the sensitivity controls, wherein the controller assigned to the smaller errors is set to a higher value than the one Regulator assigned to major errors. The smaller ones

errors are determined with the help of both channels. When t. B. a one percent error when setting the Sensitivity controller to the value 100 is detected, a two percent error should be a signal »Produce that has an amplitude twice as large and such an error is supposed to be linear under the assumption of a The mode of operation of the controller can be demonstrated when the value 50 is turned off. Larger imperfections will be proven at lower setting values that are separated by smaller distances, for example an ic ten percent error to a setting value of 10 and a twelve percent error to a setting value of 8.3 assigned. In some cases there is a switch to select a high or a low sensitivity provided in order to avoid the resulting difficulties. This solution has worked However, it has proven to be disadvantageous because the operator can very easily put the switch in a wrong position bring so the machine operates while it is not set to the correct sensitivity, yo so that either too small a number of errors is detected or that the machine in question is too is often shut down for no reason. The sensitivity control usually has a scale with a Graduation from 0 to 100. The setting value 50 on the scale of the controller is assigned for the larger errors Channel does not necessarily have the same effect as the choice of the setting value for the Controller of the channel assigned to the smaller errors. Rather, it is unlikely that the setting values the two controllers for equally high sensitivity values are the same. Therefore, each channel of each display device must have a special pulse generator be calibrated, which is difficult and time consuming. Furthermore, with the known thread monitor, which works as a function of the thread length, the controls are readjusted each time the Working speed of the slip device is changed and the controls do not allow direct or accurate reading. In practice, achieving the correct setting of the length regulator is a Change of the working speed of the slip device only by difficult and cumbersome Trying possible and the setting values to be selected differ from machine to machine.

The size of the voids, the linearity and the uniformity are factors that affect photoelectric Thread monitors are of considerable importance. Will be below the size of a flaw normally understood that percentage of the total emitted light that the defect holds back so that this part of the light does not reach the detector head. For example, a ten percent hold Error returns 10% of the light that normally reaches the detector head.

Linearity means the fact that a ten percent error means ten times as much light holds back like a one percent error, so that such an error produces a signal ten times larger generated. Uniformity in relation to the width of the warp belt is understood to mean that a defect of a certain size generates a signal with the same amplitude and without Consideration of where the flaw is in relation to the width of the warp belt, i.e. regardless on whether the defect is in the vicinity of a longitudinal edge or z. B. is located in the middle.

The invention is based on the object of creating a thread monitor of the type mentioned above, where the part serving to determine the error of the evaluation circuit is designed in such a way that changes in the error sizes of the same size are adjusted with the same size the adjustment device.

According to the invention, this object is achieved in that each amplifier has a feedback loop has, in which a variable serving as a setting device for selecting the errors to be reported Resistance and an actuator is provided, through which the resistance value of the variable Resistance and the amplitude of the feedback signal in a linear relationship with the movement of the The actuator can be changed and that the amplifier is followed by a comparator via its output signal an error counter and the cut-off relay can be controlled.

This configuration of the thread monitor or its evaluation circuit results in equally large changes of the error variables equal adjustment variables of the adjustment device and a linear change in the Resistance in the feedback loop gives a linear change in the size of the error, making it accurate Settings at high sensitivity can be achieved, not just from channel to channel but also from evaluation circuit to evaluation circuit of different thread monitors.

According to a preferred embodiment of the invention is a by the contact with the threads of the Schärbandes drivable measuring roller is provided, which generates pulses via a pulse generator, the number of which is a measure of the length of the warp belt and that of the output signals of one of the circuits Inputs of the counting device can be fed, in which the number of errors of a selected size per Unit of length can be determined. This embodiment of the invention results in changes of the same size Adjustment variables of the adjustment device that are equal to the error size, regardless of the speed of movement of the warp.

Further advantageous refinements of the invention emerge from the subclaims.

The invention is explained below with reference to the exemplary embodiments shown in the drawing explained in more detail

Fig. 1 is a side view of one embodiment of the thread monitor and shows it when viewed same from the line 1-1 in Fig.2, this Line runs between the thread monitor and the chain-erector;

F i g. 2 is an end view of the thread monitor of FIG. 1, with certain components of the upper part in FIG Section are shown and a warp beam is indicated schematically;

3 is a simplified block diagram of one embodiment of the circuit of the thread monitor;

F i g. 4 shows schematically the circuit of the amplifier, the comparator and the setting device for Setting the error size;

F i g. 5 shows the length measuring circuit of the circuit diagram in a circuit diagram which allows further details to be recognized Thread monitor, by means of which the occurring within a section with a predetermined length Errors are counted;

F i g. 6 shows in a circuit diagram further details of the length measuring circuit for measuring the length dei Defects, whereby certain parts are only indicated in general;

F i g. Figure 7 is a schematic diagram of the error counter including a decoder;

F i g. 8 schematically shows the optical system used in the thread monitor.

In the drawings, in which corresponding parts are designated by the same reference numerals, and in particular in FIGS. 1 and 2 one recognizes a warp band, designated as a whole by 10, which is between a creel, not shown, and a chain builder designated as a whole by 11 extends. The total of 12 designated thread monitor is between the creel and the Arranged chain builder and comprises a support 13 in the form of a rectangular tube, which is under the Warp belt 10 is arranged and extends transversely to the warp belt and carried by shock absorbers 14 which are arranged on two adjustable, upright columns 15. All of these parts are well known Construction. At the top of the rectangular carrier 13 are two precision guide rods 16 attached, over the top of which the warp-forming threads run, and which serve the threads to hold exactly in a certain horizontal plane in the area between the guide rods. One in Fig. The light source assembly 17 shown schematically in FIG. 8 is at one end of the rectangular carrier 13 attached near a longitudinal edge of the warp and comprises, for. B. a lamp 18, a biconcave lens 19, a plano-concave lens 20, a mask 21 with a circular opening and a glass window 22, and these Parts are arranged along an optical axis in a case so as to be strong Generate a parallel light beam that runs transversely to the path of the warp belt. On the other end of the rectangular carrier 13, a detector head 23 is arranged, according to FIG. B. a glass window 24, a mask 25 with a rectangular opening, a plano-convex lens 26 and a phototransistor 27 which are arranged to take that of the light source assembly 17 across the warp Record emitted light, so that the phototransistor generates an output signal that corresponds to the intensity of the incident light is proportional and therefore to a determinable way varies in relation to the proportion of light that passes through the threads and approximately existing yarn defects is retained, which pass through the light beam.

According to FIG. 1, the threads coming from the creel run along converging paths first of all a set of thread guides 28 and then parallel to one another a rod 29 acting as a hold-down device and a reed or a comb 30. The rod 29 and the reed 30 are both at their ends outside of the Longitudinal edges of the coulter belt 10 supported by vertically arranged support members which extend from the shock absorbers 14 upwards. After passing the comb 30, the threads extend over the top of the thread guide rods 16, by means of which they are held in a horizontal plane and in alignment with the optical axis of the collimated light beam between the light source assembly 17 and the detector head 23. After the light beam has passed, the threads are baptized over a measuring roller 31, which is rotated according to the running speed of the threads by the frictional connection between the threads and the roller, and beyond the measuring roller, the threads are wound onto the warp beam 11. The electrical circuit of the thread monitor comprises an amplifier housing 32 and a relay housing 33, both of which are attached to one of the columns 15, a pulse generator 34 assigned to the measuring roller 31 and a counter housing 35. Electrical lines connect the counter in the counter housing 35 with the pulse generator 34 and the amplifier assembly in the housing 32.

F i g. 3 is a simplified block diagram of the electronic evaluation circuit of the thread monitor at certain circuit elements are only indicated schematically in order to simplify the description to facilitate the electrical operation of the thread monitor. More details of the whole in Fig. 3 are shown in FIG. 4 to 7 can be seen. According to FIG. 3, the evaluation circuit includes three circuits or channels, one channel 36 associated with major errors and one minor Channel 37 associated with errors and a channel 38 which operates with reference to the length of the threads

ίο will. The main channel 36 is usually only set to such a sensitivity that it reports the larger errors, counts them and, if necessary, shuts down the chain-erector so that the defects can be eliminated. The channel 37 associated with the smaller errors is usually set to a higher sensitivity and it detects both small errors and the larger errors mentioned. However, the channel 37 is usually only used to count these errors, not to shut down the chain builder. The length-dependent channel 38 counts the errors as a function of the thread length and can be set in such a way that it stops the chain builder if necessary.
If an error is detected, the detector head 23 generates a negative pulse proportional to the size of the error, which is fed to the inputs of the channels 36, 37 and 38 via a branching line 39. The negative pulse fed to the channel 36 for the larger errors is increased

a capacitor 36-C1 which, in a manner to be explained, may be a set of capacitors to which a selector switch is assigned and via a resistor 36-λ 1 to the input; Functional amplifier 36-A is supplied, which comprises a voltage divider which has a step-wise adjustable resistor 36- /? 3, which is shown as a potentiometer for the sake of simplicity, and a connected resistor 36- /? 4 includes.

A feedback resistor 36- /? 2 establishes a < connection between the sliding contact of the adjustable resistor 36- /? 3 and the input of the amplifier 36-A. The ratio between the resistance values of the resistors 36 · /? 2 and 36 · /?

as well as the setting of the adjustable resistors 36 · /? 3 determine the gain of amplifier 36- A, which is highest when the rotary knob de resistance is turned all the way to the left and ar lowest when the rotary knob as far as it will go

to the right turned 1st. This feedback arrangement

allows the device to easily correspond directly

to calibrate the size of the imperfections; then we

In the following, discussed in more detail. The output signaides function amplifier36-Λ1

The form of a positive pulse is generated via a resistor 36- /? 7 is fed to the input of a comparator 36- B , which is simply a further functional amplifier, but without a negative

- ■. »■« # · ■

Feedback is about. A reference voltage of -1 V, which is taken from a voltage divider comprising two resistors 36-R 9 and 36- R 10, is also fed to the input of the comparator 36-B via a resistor 36-Λ8. If the positive output pulse of the amplifier 36-4 is higher than the reference voltage of 1 V, the comparator 36-β switches from a positive output voltage of approximately 10 V to a negative voltage of approximately the same amplitude or size. The comparator will remain in this state until the input voltage returns to a voltage slightly lower than the reference voltage. With the output of the comparator 36-ß is a resistor 36- /? 11, the other end of which is connected to a voltage divider comprising two resistors 36-Ä5 and 36-Ä 6, which is connected to the input of the comparator. This is a positive feedback arrangement, by means of which the switching action of the comparator 36-β is improved, that is to say which ensures a faster response of the comparator. The negative output pulse of the comparator 36-ß is fed via a capacitor 36-C2 to a monostable multivibrator 36- D , which generates an output pulse with a duration of about 50 milliseconds, which is fed to a counter driver amplifier 36- £ and whose length is sufficient to produce a Actuate counter 36- F for the larger errors. The output pulse of the counter driver amplifier 36- £ thus actuates the counter 36-F for the larger errors, which is designed as an electromechanical device. The output of the counter driver amplifier 36- £ is fed to a movable contact 40a of a circuit breaker 40-SW, and when this switch is in the operating position, a signal is fed to an OR gate 41, which in turn feeds an output signal to a relay driver amplifier 42, the output of which actuates a control relay REX , by means of which the chain-erector 11 can be stopped.

The circuit and mode of operation of the channel 37 assigned to the minor errors correspond to FIG Circuit and mode of operation of the channel 36, apart from the fact that the adjustable resistor 37- /? 3 to one Smaller error size is set than for the channel 36, and that the contact 40 / j of the switch 40-SW takes its rest position. In this channel, the response tree is not shut down, but a Number of errors activated.

When monitoring the number of errors per length unit , a known type of thread monitor usually converts the error signal into a square-wave pulse of constant height and integrates these pulses with the aid of an FTC element in order to generate a signal that is more or less proportional to the duration of a SS single error signal or a set of error signals 1st. Of course, a similar device works as a function of the working speed of the chain-erector or the warping device, and it has to be adjusted every time the working speed of the device is changed. Since the integration capacitor is provided with a discharge path, the distances between the error signals affect the output voltage of the integration device, so that it is uncertain whether the circuit ^fi i has been set correctly and that a compromise can at best be reached.

In the case of the thread monitor described, one is completely

another solution envisaged. A pulse generator 34, which generates 120 pulses per revolution, is with the measuring roller 31 of the chain builder 11 connected. The measuring roller 31 usually has such a circumferential length that the Distance between every two pulses corresponds to a certain thread length unit and the pulses through Decade counter can be processed. The use of the pulse generator in the inventive Thread monitor enables the thread length to be measured precisely at any time, regardless of the operating speed of the slip device, and it allows the use of a directly in units of length, z. B. inches or centimeters, readable length selector switch.

It is believed that for most thread monitor users, the number of errors per unit length of the threads is of more interest than the actual length of the imperfections. Hence the channel 38, which works as a function of the thread length, is normally designed to match the number of Measures errors per selected unit of length. In the case of channel 38, the error pulse is generated by a function amplifier 38-Λ amplified and as with channel 36 for the larger errors by a comparator 38-ß with compared to a reference signal. However, the output of the comparator 38-β becomes two counting circuits 43 and 44 supplied. The counting circuit 43 for the selected thread length eliminates both counting circuits 43 and 44 the reset voltage so that both counting circuits can operate. The lower counting circuit 43 in Fig.3 measures the length of the threads that should be monitored after an error has been detected by counting the pulses of the Pulse generator 34. This length is selected with the aid of a switch, not shown, which causes both counting circuits are reset if the number of errors has not already been reached that with the aid of the switch mentioned for the upper error counter circuit 44 has been selected. Will the selected number of errors is reached, a negative pulse is fed to a monostable multivibrator 38-D, the in turn actuates a counter drive circuit 38-£ and a length counter 38-F. If the Contact 40c of the switch 40-SW is in its operating position, then the slip device U shut down. This length counting circuit is described in more detail below.

1st 4 shows further details of the circuit of the larger errors associated channel 36. According to Figure 4, in which one schemaüsches example of a circuit including a phototransistor Ql-23 for the detector head 23 illustrated, the negative pulse of the detector head 23 is a capacitor 36-CM is fed to a resistor 36- / 71, which is connected to the input of the functional amplifier 3β · Α . The switch 36-SW1 is a selector switch for the lower limit frequency of the amplifier 36 · A _1, which selects one of three capacitors 36-C1A 36-Cl0 and 36-Cl C, the capacitance of which determines the lower frequency of the amplifier 36-Λ. It is desirable to have maximum sensitivity at a low frequency, but the harshness due to movement of the warp belt usually prevents the use of the lowest frequency switch position unless the flaw size control knob is set to do so a response to a fairly large mistake

709627/92

is guaranteed. The output signal of the amplifier 36-A is inverted and fed to the base of a transistor 36-Ql , which is connected as an emitter follower and serves to amplify the output current of the amplifier 36-i4, since its output has a rather low load capacity. The output signal of the transistor 36-ζ) 1 is fed to a voltage divider, which has a fixed resistor 36-A4 and a resistor group 36- /? 3 with a plurality of resistors 36-R3A to 36-R3K . The feedback resistor 36- /? 2 is connected to the top resistor 36-R3K, which is associated with an error magnitude of 12%, and this connection is made by switch 36-SIV2. In this position of the switch, the gain of the amplifier 36-Λ is determined by the ratio between the resistor 36- R 2 and the resistor 36-R 1, which has the value 1.666. A 100% error signal produces a 5V pulse, so a 12% error produces a 600 millivolts signal. The product of the resistance ratio of 1.666 and the signal voltage of 600 millivolts is thus 1 V and this is the desired output level of the amplifier. On the same basis, a 1% error signal produces a 50 millivolt signal that requires a gain of 20. This is the gain that amplifier 36-Λ has when the feedback resistor 36- /? 2 according to FIG. 4 is connected to the contact R3A at the lower end of the resistor set 36-R 3. The voltage divider for the output voltage increases the gain of amplifier 36-Λ in the setting for 1% by a factor of 12.

A zero point regulator 36-R 13 is also provided, which compensates for the small displacement voltage present at the input of the amplifier 36-. This regulator is part of a voltage divider, the resistors 36- /? 12, 36-R 13 and 36 · /? 14 includes, which are located between terminals to which a DC voltage of + 15V or -15 V is supplied. This compensation voltage is fed to the input of the amplifier 36- / 4 via a resistor 36-R 21. A capacitor 36-C4 bridging the resistor 36-R 2 is used to limit the upper limit frequency of the amplifier and to switch off all high-frequency noise signals. A capacitor 36-C3 is also provided, which forms the frequency compensation capacitor for the amplifier and prevents the amplifier from oscillating. In the drawings, the capacitance values are given in microfarads if no other unit is specified. Furthermore, resistors 36 · A16 and 36 · /? 18 which are current limiting resistors for amplifier 36 * A and transistor 36-Q1. SS

The positive output signal of the transistor 36- Q 1 is fed to the input of the comparator 36 · B via a resistor 36 · /? 7 and compared by the comparator with a voltage of exactly -1 V, which is a two resistors 36 · /? 9 and 36 · R 10 include - βο the voltage divider is taken. This reference voltage is applied to the input of the comparator via a resistor 36 · /? 8 supplied. When the output of the transistor is about 1 V, the working with a very high gain comparator ⁶ S of the same size switches 36 · B of a negative voltage of about 10 V at its output to a positive voltage of approximately around. The resistor 36-11 and the voltage divider resistors 36-6 and 36- / 75 form a positive feedback loop to improve the switching effect of the comparator.

It can thus be seen that the sensitivity regulator of the amplifier channel to select the size of the imperfections with the help of the selector switch 36-5VV2 has a negative feedback loop with the resistor 36- /? 2 and one the resistors 36-R3A to 36-R3K and 36- /? 4 comprising voltage dividers, both of which bypass the output of amplifier 36-A . The gain of the amplifier is determined by the feedback ratio and the ratio between the resistance of the tapped part of the voltage divider and the total resistance of the voltage divider, if one neglects the very small loading effect of the feedback resistor. The accuracy with which the size of the flaws can be set with the help of the selector switch 36-5W2 depends primarily on the tolerances of the feedback resistor and the resistances of the voltage divider, the latter being graded according to 1% of the error size, as the one described Feedback arrangement and the high gain amplifier 36-A are provided. The resistance values of the resistors used in the voltage divider are linearly related to the size of the voids, but they vary the gain linearly in a reciprocal manner. Of course, the voltage divider, designed as a step switch, could also be replaced by a linear potentiometer, the sliding contact of which is rotated in a linear relationship to the size of the imperfections.

The switching of the channel 37 assigned to the smaller flaws corresponds to that of the channel 36 assigned to the larger defective parts, the switching of the channel 37, which corresponds to the switch 36-S W2 of the channel 36, being assigned to a smaller area and the switch contact 40 £ > is normally in its rest position. The switching of the various stages of the channel 38, which operates as a function of the thread length, is also the same up to zi the comparator 38-ß as in the channels 36 and 37.

Fig. 5 shows schematically the circuit of the two counting sounds 43 and 44 of the channel 38 for the case that the number of errors per selected length unit is to be determined. If, according to Figure 5 dei detector head 23 is responsive to a defect, the Ungenkomparator erzeug 38-ß a positive pulse about 10 voi V ₁ of a voltage divider comprising resistors zwe 43/723 and 43 /? 26 is supplied which reduces this voltage to such a level that it is suitable for the NOR gate used in the circuit. The at the connection point between the resistors 43 · /? Pulse appearing 23 and 43 · R * is fed to an input of a NOR gate 43-01, so that a high level appears at its output. The output signal of this first NOR gate is fed to an input of a second NOR gate 43-02, at the output of which a low level then appears. The output of the second NOR gate 43-02 is connected to the other input of the first NOR gate 43-01. Thus, the two gates are cross-coupled to form a locking circuit 43- L. This locking circuit remains in the just described

■ * «

benen state until a positive pulse is fed to the other input of the second NOR gate 43- G 2. A diode 43-C /? 1 serves to protect the first NOR gate 43-G1 against the high negative voltage which is normally present at the output of the comparator 38-5.

The low output level of the first NOR gate 43-Gl becomes the base of a transistor 43 - <? 2 fed so that this transistor turns off. As a result, there is no longer any voltage drop across a resistor 43- /? 27 at the emitter of transistor 43-ζ) 2 from, and In addition, the reset voltage disappears for all decade counters 43-Wl to 43- / 73 and 44-Hl which z. B. can be the usual integrated decimal counter, both in the case of the length counter as well as the error counter 44. All decade counters are now reset and ready, with a To start counting. In the reset circuit of the three decade counters 43- / 71 to 43- / 73 of the length counter 43 is a current limiting resistor 43- /? 2 provided.

The pulse generator 34, which is preferably a photoelectric generator which generates 10 pulses for every 1 inch or 25.4 mm length of the threads, generates positive pulses of about 10 V during the entire operating time of the chain-erector 11 are fed to a voltage divider comprising two resistors 43 - /? 30 and 43 - /? 31, which reduces this voltage to a level suitable for the first decade counter 43 - / - / 1. These pulses are counted by the three decade counters 43- / 7, 1.43- / 72 and 43- / 73. The output signal of the third decade counter 43- / 73 generated in binary form using the 8-4-2-1 code is fed to a buffer circuit 43- / which is formed by four inverter amplifier stages, one of which is each output of the decade counter assigned. When the output of the stages of the decade counter 43- / 73 is a low level, the output of the buffer circuit 43- / 73 is high. The output signal of the buffer circuit is fed to a decoder 45 which converts its binary input signals into decimal output signals. The length selector switch 43-SlV is set in Fig. 5 to a length of 10 inches or 254 mm. After the pulse generator 34 has measured a lungs of 10 inches, the Dckodicrcr 45 generates a positive pulse, which through a capacitor 43-C9 to a resistor 43- /? 29 and an input of two NOR gates 43-G3 and 43-G 4, these gates being connected so that they form a monostable multivibrator 43- /. The positive output pulse of the monostable multivibrator is fed to the other input of the NOR gate 43 · G 2 of the locking circuit 43 · L. A resistor 43- / 728 and a capacitor 43-C6 form the timer for the monostable multivibrator. This circuit causes the latch circuit 43- L to return to its initial state and to apply a reset signal to all decade counters in order to interrupt the counting process. The to transistor 43-Q3 is operated by the monostable multivibrator 43-7 and forms a switch which bridges the input of the latch circuit 43 · L and serves to remove all signals from the comparator 38 · θ which could prevent the latch circuit and the decade counters are reset. The length counter 43 is now ready to be actuated by the next error signal emitted by the comparator 38-0.

At the same point in time at which the first error signal of the length comparator 38-ß eliminated the reset signal in all decade counters, the first error signal was also sent to a two resistors 44- /? 33 and 44- /? 34 comprehensive voltage divider supplied, which has to fulfill the same task as the voltage divider described with the resistors 43- /? 25 and 43 - /? 26. The pulse of the voltage divider 44 - /? 43, 44- /? 44 is fed to the input of the decade counter 44- / 71 of the error counting circuit 44. Any error signal which occurs during the measuring period corresponding to a thread length of 10 inches or 254 mm is also fed to this counter 44- / 71. The output signal of this counter is fed to a further buffer circuit 44- / and a decoder 46, which work exactly in the same way as the corresponding circuit elements of the length counter 43. Since the selector switch 44-SlV has been set to the position for two errors, the Second errors lead to the generation of an output pulse which, according to FIG. 3, would trigger the monostable multivibrator 38-D connected upstream of the counter drive amplifier 38-E. As a result, the mechanical counter 38-F would be actuated and the chain-erector 11 would be stopped when the contact c of the switch 40-SW is in its operating position. If only one error occurs during the counting period corresponding to 10 inches of thread length, the length counter 43 resets all of the decade counters so that the mechanical counter is not actuated and the chain pruner is not stopped.

F i g. 6 shows schematically the optical length measuring device in which the same length counter 43 is used, which is therefore only indicated in FIG. 6 by a dot-dash rectangle; however, in this arrangement, the flaw counter 44 is replaced by a counter 47 which measures the length of the flaws. A ncgalivcr output pulse of the comparator 38- B opens a shunt switch in the form of a transistor 47- (? 4 and allows pulses from the pulse generator 34 to reach the two counters 47- / 71 and 47- / 72. These pulses are counted and buffered and decoded as described with respect to the error counter 44. Since the selector switch 47-SW has been set to the 1 inch (25.4 mm) position, a defect 1 inch (K) in length would cause that the Dckodicrcr 48 emits an output pulse. This would lead to the actuation of the mechanical counter 38- F and to the shutdown of the Kcttcnuufbäumcrs 11 when the contact of the switch 40-SW has been brought into the operating position.

The same process would occur if the comparator 38- B were actuated by two errors, each 0.5 inch in length. The only difference would be that the comparator 38-0 and bypass switch or transistor 47 · Q 4 would be operated twice. The transistor allows only signals from the pulse generator to reach the Dckadenzählererr 47-Hl and 47-W 2, while the Kompurutoi 38- B is actuated by an error signal. In this way, the defect length counter 47 measures the length of one or more defects.

Figure 7 is a schematic representation of the divider of the error counter 44, which is connected to the decoder 4f is provided. When the decade counter goes back 44 - / - / 1 ' is set, all output connections 2,3,4 and J

a high level. When an error signal is applied to the counter, the output terminal goes off 5, which has the value 1, has a low level. Two input signals result at connection 4, which has the value 2, a low level and at the terminal 5, which has the value 1, a high level Level. Three input signals cause the terminal 5 to go low again, and that terminal 4 maintains its low levels. Other input signals operate the counter on similar ones Wise.

The buffer circuit 44- / inverts the output of the decade counter 44 - // 1 so that the low Output levels of the decade counter result in high output levels at the output of the buffer circuit. In which Counting result "3" in the buffer circuit would show connections 3 and 6 a high level.

The decoder 46, which is used in connection with the counting circuits, is made up of diodes in a very simple manner and works as follows: If the counting result was "1", a high level would appear at output 3 of the buffer circuit 44- /, and none would appear Decoding may be required. The output signal is fed directly to contact 1 of the selector switch 44-5 W. With the counter result "2" a high level would appear at output 6, which is fed directly to contact 2 of the selector switch. If the count result was "3", the terminals 3 and 6 would have a high level. A diode 46-CR 4 is connected to output 1 and a diode 46-C7-5 is connected to output 2. The anodes terminals of these diodes have a resistor 46- /? 40 connected, at the other end of which is a DC voltage of +5 V. Since when the counter result "3" appears at the outputs of the buffer circuit 44- / corresponding to the values 1 and 2, the diodes 46-CR 4 and 46-CR 5 are reverse biased and appear at the an or these diodes a high voltage applied to the contact 3 of the selector switch 44-SW . If the level at the output corresponding to the value 1 were low, a current would flow through the diode 46-CR 4 and at the anodes of the diodes 46-CA 4 and 46-CR5 would be a low voltage

to appear. The decoder 46 operates on the remainder Switch positions in a similar manner.

In addition 5 sheets of drawings

Claims (6)

Patent claims: 1. Thread monitor, which responds to bead-like thread thickenings in a warp belt, which moves in a plane through a light beam that strikes a photodetector, which generates an output signal, the amplitude of which is a function of the brightness of the incident light beam and which is an electronic evaluation circuit can be fed, which has two or three adjustable and addressable circuits for certain error sizes, each of which has an amplifier and via the outputs of which a switch-off relay can be controlled to stop the warp belt, characterized in that the amplifier (36/4, 37A, 3SA) has a feedback loop in which a variable resistor (36- / 3, 37-Ä3, 38-Ä3) and an actuator (36-SW2) are provided, through which the resistance value of the variable resistance (36-Λ3, 37-R3, 3S-R3) and the amplitude of the feedback signal is variable in a linear relationship to the movement of the actuator (36-5 ^ 2), and that the amplifier (36A, 37 A, 3SA) is followed by a comparator (36A, 37 B, 3SB) whose output signal is an error counter (36F, 37 /% 38f) and the cut-off relay (REi) can be controlled. 2. Thread monitor according to claim 1, characterized in that the variable resistor (36 - /? 3.37 - /? 3.38 - /? 3). Several series-connected V / resistance sections (36- R 2A to 36-R3K ) mh equal resistance values, which are provided with contacts which are connected to the nodes between adjacent resistor sections, and that the actuator is a movable switch contact (36-SW2) which can be connected to the contacts to change the amplitude of the feedback signal . 3. Thread monitor according to claim 2, characterized in that the contact spacings are steps of 1% in a linearly increasing series of defect size percentages. 4. Thread monitor according to claim 2 or 3, characterized by a first fixed resistor (36- R 1, 39-R 1) arranged between the phoiodetector (23) and the input of each amplifier (36- / 4, 37-A, 3SA) ) and a second resistor (36- R 2, 3S-R 2) connected between this input and the switch contact (36-SW2) in the feedback loop, the ratio between the resistance values of the first and second resistor having a first selected gain for the amplifier (36- / 4, 37-A 3S-A) determines when the switch contact is applied to the contact assigned to the greatest fault, and the two resistors (36-Ä1,36-Λ2,38-Ä1, 38- R 2) together with the resistor sections (36-R3A to 36-R 3K) determine gain levels for the amplifier which increase linearly when the switch contact is brought into contact with contacts associated with progressively smaller error sizes. 5. thread monitor according to any one of claims 1 to 4, characterized in that the comparator (36- B, 37-B, 38- B) as a function of amplified Output signal levels that are below or above a selected value, a first and a second, respectively Condition. 6. Thread monitor according to one of the preceding claims, characterized by one by the Contact with the threads of the warp belt (10) drivable measuring roller (31), which is controlled by a pulse generator (34) Generates pulses, the number of which is a measure of the length of the warp belt and which are with the output signals of one of the circuits can be fed to the inputs of a counting device (43, 44) are, in which the number of errors of a selected size per unit of length can be determined is.