DE964645C - Device for checking textile threads - Google Patents

Description

Device for checking textile threads The invention relates to a Device for checking textile threads, which is characterized in particular by this. that in a branch of a (-renerator circuit with electron tube a capacitor is recorded, the reactance of which determines the power generated, or at least participates. and that the generated high-frequency vibrations by means of a detector, whose output circuit is connected to a relay circuit to which the rectified Pulses are fed to be rectified.

In the production of textile threads it is known to kj-ntrollieren, whether there are thickened or tapered areas in the threads. The thickened parts, which are known to affect the appearance of the threads and weaving faults as the cause are referred to as "slub" in this description.

These are generally thickened areas about the length of corresponds to the mean fiber length.

Thickenings that are considerably shorter affect the appearance of the thread generally very little and these need not be removed.

It is known that these "slubs" are made with the help of an electrical capacitor to prove. why the Threads between the electrodes of the capacitor be guided. As soon as a thickened stefle is between the capacitor plates the capacitance of this capacitor changes, and with the help of a with the current source connected to the capacitor can generate a current change, which can be used to form a pulse that works on a relay, which cuts the thread or clamps it in such a way that it breaks. The slub is then removed, the ends tied together, and then the thread can continue be pulled through the apparatus.

In the usual process, those generated in the condenser circuit are generated Voltage changes amplified before being fed to a relay.

The gain required is very large, and generally needs for this purpose amplifiers with several electrons are tubes.

The invention relates to a device, which is also a capacitor is used as an aid in finding the slubs. Its purpose is to be a The simplest possible setup of a device working with a capacitor for Finding the slubs to form, and essentially that a capacitor is connected in a tube generator circuit and arranged such that when it passes through of a slub the energy consumption of the circle is changed.

This changed energy absorption comes as a change in the oscillation amplitude to the effect, and after the rectification and separation of the existing ones High frequency components are the low frequency current or voltage for actuation of a relay is used.

The low frequency voltage obtained in this way has the character of a pulse, and according to a particular embodiment of the invention this can Pulse can be obtained in that in the generator circuit in addition to the positive A negative feedback is used, preferably through a feedback Parallel arrangement of self-induction and capacitance is formed, which forms a blocking circuit represents.

The resonance frequency of this trap circuit should preferably be relative differ little from the generator frequency. With this arrangement, the vibration amplitude changed in the frequency-determining circuit as soon as the value of one of the parameters of the generator circuit or the negative feedback circuit is changed.

This change in amplitude can be done with the help of a rectifier or of a detector into low: frequency voltage fluctuations. These Voltage fluctuations can e.g. B. via an RC filter, in which the high frequency components are suppressed, are fed to a relay circuit. As a relay, according to of the invention, in particular a thyratron, can be used in its anode circuit a magnetic relay, e.g. B. a telephone relay is switched.

When passing a slub, a positive pulse is applied to the control grid of the thyratron generated so that the thyratron is conductive.

A galvanic connection of the grid of the generator tube with the The grid of the thyratron is undesirable because of the creeping of the direct current potential the limit value of the pulse changes, whereby the thyratron becomes conductive.

For this reason, according to the invention, in front of the control grid of the Thyratrons switched a capacitor, and the control grid is over a high resistance Resistance connected to a point whose potential is negative relative to the cathode is.

You can also arrange the circuit so that the passage of a Slubs cause the condition necessary for the generation of the vibrations, z. B. by weakening the negative feedback. This negative feedback must then be chosen so that the positive feedback present in the system is balanced will.

As a result of the change in capacity that occurs when passing through a slub of the measuring capacitor, the oscillations are then generated. The negative bias of the grid is preferably chosen in this case so that in the idle state Slope is lower than the maximum slope.

As soon as the system generates vibrations, the anode current becomes direct changed, and this change in current can operate a relay. The relay is through bridged a capacitor that allows the high frequency currents to pass through.

Further details of the invention are based on a drawing, which represents some exemplary embodiments, through the description below explained in more detail. The electrode capacitances are omitted in the drawing. So far it might be necessary to use these capacities in a manner known per se neutralize or otherwise render harmless.

Figure I is a complete schematic of a circuit including a thyratron; FIGS. 2 and 3 schematically represent generator circuits which, when there is a change a capacitor begin to oscillate; the DC power sources are in the figures not drawn; 4 shows an exemplary embodiment which has been tried and tested in practice represent.

In Fig. I, I is a triode connected as a generator; 2 is a Thyratron. The generator circuit is a so-called "Hartley" circuit or three-point circuit, a blocking circuit 8 and 9 being included in the cathode line. Between the Control grid of the triode and the oscillating circuit 6 and 7, a capacitor 3 is connected, which is bridged by a discharge resistor 4. The grid is further over the resistor 5 and the capacitor 10 with the terminal facing away from the cathode of the trap circuit connected.

The junction of the resistor 5 with the capacitor 10 is Connected to the grid of the thyratron 2 via a capacitor II. This grid is also connected to a resistor I2, the other end of which is connected to a point is connected, the potential of which, relative to the cathode, is negative.

The winding of a telephone relay is located in the anode circuit of the thyratron I3, and there is also a resistor 14 to limit the thyratron current connected in series.

The effect of the generator circuit is readily apparent. The condenser g of the negative feedback impedance is in this case the measuring capacitor, between whose electrodes the thread is guided. As soon as a slub is in the space between the Electrodes, the negative feedback impedance is changed. It changes also the amplitude of the generated vibrations, and this change in amplitude causes a change in the mean voltage on capacitor 3 and thus on the control grid the generator tube. The changes in the mean voltage are due to the Capacitor 11 is fed to the control grid of the thyratron.

It is also possible to include the measuring capacitor in the generator circuit and not to change the negative feedback impedance. Then the generator frequency changed, and as a result of this change, the required change in the negative feedback.

With a certain amount of change the thyratron becomes conductive and actuates relay I3. The sensitivity, i.e. H. the peak value of the impulses, at which the thyratron becomes conductive can be regulated by changing the negative Bias of the thyratron grid changes. If this bias is chosen so that a small change is enough to make the thyratron conductive, then it is enough a pulse with a low peak.

Slow changes are due to the presence of the capacitor 11 not passed on to the grid of the thyratron. This has the advantage that one the thread with your hand in the space between. can place the capacitor electrodes, without the thyratron becoming conductive.

In Fig. 2, I is also a triode. In the cathode lead of this Triode is a blocking circuit added by a capacitor g and one with it self-induction 8 connected in parallel is formed. Between the anode and the blocking circuit the self-induction coils 15 and I6 are connected, and between the grid and the A capacitor 24 is connected on the high-voltage side of the coil 15.

The last-mentioned elements form a voting circle in and of themselves known generator circuit.

The blocking circuit 8 and 9 again serves as a negative feedback line, and the circuit is adjusted so that it does not yet generate any oscillations. The negative feedback impedance must then have a value so high that the positive Feedback is compensated. A relatively small change in the trap capacitor is already sufficient to enable the generation of vibrations.

When setting at the base of the characteristic curve, i.e. at a point where the slope is low, then the anode current suddenly increases sharply, and a Relay 18 switched in the anode circuit, which is bridged by a capacitor I7, is operated. This relay has the same task as relay I3 from Fig. I, which is connected in the anode circuit of the thyratron.

But you can also change the voltage generated at capacitor I7 use to make a thyratron conductive in a manner similar to that in FIG.

Of course, the generated high-frequency voltage can after it is rectified by means of a special detector can also be used, to make a thyratron conductive or to operate a relay in some other way.

The circuits described are only exemplary embodiments, and the purpose of the invention can also be achieved with other types of circuitry. However, it is always essential to use a tube in a generator circuit, whereby by the movement of the thread between the capacitor electrodes the amplitude of the generated vibrations is changed or the vibrations are generated.

In Fig. 3 is a circuit with negative voltage feedback shown. I is a triode, 19 is a self inductor that connects to the capacitor 20 and the capacitors 21 and 22 forms a tuning circuit. The self-induction coil 23 is between the connection point of the capacitors 2I and 22 in this case and switched to the grid. This coil is coupled to the coil 19, namely such that it produces positive feedback.

The capacitors 21 and 22 create negative feedback, which offsets the effect of the existing positive feedback. If the feedback is chosen to be considerably larger than is necessary per se for the generation of vibration would also have to have the negative feedback, which is the effect of the positive feedback balances, also be very strong, and in these circumstances one becomes relative small changes in negative feedback cause vibrations to be generated.

A similar consideration applies to the circuits of Figs 2.

In the case of Fig. 3, one can make the required change to the negative Feedback obtained in that the capacitor 22, which in this case as a measuring capacitor serves, is changed '. You can also choose between the grid and anode and between a grid and cathode switch oscillation circuits that have the same resonance frequency and be formed by a self-induction connected in parallel with a capacitance and which include a third tuning circuit in the anode lead.

The two first-mentioned circles form a negative feedback, that when the capacity of the first-mentioned circle is increased into a positive one Feedback can pass.

The main part of the devices according to the invention is that with a very simple apparatus sufficiently strong impulses are received, to operate the relay.

Instead of the thyratron, other devices can of course also be used use, e.g. B. a "trigger" circuit, which when a pulse arrives at the Grid one of the tubes. turns over.

As soon as the relay 13 comes into effect and the thread is broken. is, if the anode current is interrupted for a short time, the slub is eliminated, and the ends of the thread are tied together.

In the device according to FIG. I, the one on the grid of the thyratron incoming impulse positive if a slub, i.e. a thickening of the thread, is in the Capacitor arrives, while when passing a tapered part a negative one Impulse appears. If one wants to get rid of the tapered parts, the direction can of the pulse can be reversed, e.g. B. by interposing a triode or by Recording of a high-frequency decoupled impedance in the voltage supply line the oscillator anode. The anode then has an impedance and a separation capacitor connected to the control grid of a thyratron.

When using several. Apparatus of the type described can a central supply can be used, whereby the power of the feeder must be selected according to the number of devices to be operated.

It is desirable to stabilize the food apparatus because otherwise the sensitivity of the whole apparatus to too great a degree to changes in the mains voltage could be dependent.

Because the heating voltages cannot be stabilized without complicated arrangements it can happen. that when the heating voltage changes, the voltage changes that must be fed to the grid of the Thyra tron. in order to conduct this do. In order to eliminate the difficulties caused by this, according to the Invention the negative bias of the thyratron by rectifying the heating voltage be generated.

Under these circumstances, the changes in tension will be the can make the thyratron conductive, insofar as they are caused by changes in the heating voltage find almost completely balanced.

In Fig. 4 an embodiment is shown that in practice has been tried and tested and works very reliably. The basic circuit is the same that of FIG. I. However, only one triode is used in the example of FIG a double triode has been used in the arrangement according to FIG.

The first triode of the double tube I is in exactly the same way as in Fig. I connected as a generator tube. With 6, 32, 33, 34 is the generator circuit and denoted by 8 and 9 of the blocking circuit lying in the cathode line.

The leakage resistor 4 and the grid capacitor 3 are again available, only the AbX line resistance is not directly parallel to the grid capacitor 3 connected, but between the grid and the end of the facing away from the cathode Blocking circle.

The anode voltage is via the anode resistance 3I of the tap the generator coil 6 is supplied.

The measuring capacitor 32 is in the generator circuit and is through the capacitors 33 and 34 are cut off from the DC voltage so that this capacitor is touched can take place without danger.

The series connection of the capacitors 32, 33, 34 forms the equivalent of the individual capacitor 7 in the circuit according to FIG. I.

It goes without saying that the capacitance of the capacitors 33 and 34 is many times larger than that of the capacitor 32, hence a change in capacitance of the capacitor 32 has the greatest possible influence on the frequency of the generator circuit Has. The tap of the coil 6 is grounded via the capacitor 35. This capacitor is dimensioned such that it has a very large impedance for low frequencies and represents a short circuit for high frequency. The tap is still protruding the capacitor 36 in connection with the grid of the second triode 1a of the double tube, and in the usual way the grid is connected to the cathode via the bleeder resistor 37 connected to the second triode of the double tube.

The anode of this second triode is through the resistor 38 with the positive terminal of the anode power source connected. This anode is next through the small capacitor 39 with the cathode for the purpose of suppressing any high frequency voltages connected between the anode and cathode of this triode. The anode of this second tube is connected in the usual way by means of the capacitor 40 to the control grid of the thyratron tied together. Between this capacitor and the control grid of the thyratron is a Resistor 41 switched, the purpose of which will be explained later.

The leakage resistance 42 has a particular one with one point Voltage source 51 connected, which provides the required negative grid voltage for the tubes supplies.

The thyratron 2 is connected in exactly the same way as in Fig. I. In the anode circuit of the thyratron is again the relay 13, which is used, to cut the thread when a slub arrives in the measuring capacitor.

The thyratron and the double tube are supplied by separate anode power sources 50 and 52 fed.

The two anode power sources are by means of gas-filled stabilization tubes 43 and 44 stabilized.

Otherwise, the two anode power sources are in the usual way executed as rectifier circuits with means for suppressing the on the DC voltage superimposed AC voltages, so that a detailed description is over liquid. These anode power sources and the rectifier circuit for the Lattice prestressing are preferably built into a box and to serve for feeding a group of circuit arrangements of the type mentioned above. The rectifier circuit 51 is not stabilized. This shifts when the line voltage changes the negative bias a little, so that a change in the grid voltage, where the thyratron becomes conductive as a result of the changed mains voltage, for the most part is balanced.

These circuit arrangements contain the double triode and the thyratron in small, preferably dust-free boxes that are close to the take-up reels are arranged for the textile thread. The mechanism is also located on the box which cuts the thread or, if necessary, clamps it.

The box containing the central feeding apparatus can be attached to any appropriate place.

A relay 45 is included in the anode power source of the thyratron, whose winding is bridged by a capacitor 46 and whose contact is the feed line can interrupt.

With this arrangement, a greater number of circuits of the type are fed according to FIG. The part of the apparatus that has the double tube and the Contains thyratron, differs from Fig. I only in that that by the change The voltage pulse generated by the measuring capacitor is not immediately released from the grid of the generator tube is transmitted to the thyratron grid, but that this pulse through the resistors 31 and 38 is reinforced twice. With this two-fold reinforcement the remains Polarity of this impulse unchanged because this contradiction would change both @as signs of the pulse reverse, so that the polarity relationships at the lattice of the thyratron remain unchanged.

The circuitry of this part of the apparatus thus works precisely the same way as the circuit in Fig. I. The inclusion of relay 45 in the The purpose of the anode power source for the thyratrone is to supply a large number To facilitate thyratron circuits by means of a central power supply.

The effect is as follows: Contact 47 is normally closed, and as long as the threads that run through the measuring capacitors do not have any thickened areas all thyratrons are de-energized. But as soon as a slub in the measuring capacitor arrives, the voltage of the thyratron grid is changed so that the concerned Thyratron becomes conductive.

So that the thyratron, after it has become conductive, to intercept of a slub does not remain conductive all the time is a self-breaking contact 47 provided in the feed line.

This contact is actuated by relay 45. In parallel with the relay winding the capacitor 46 is switched, whereby the opening of the contact by a short Time is delayed. This will give the relay I3 time to work properly.

On the other hand, the contact may only remain open for a short time because, as long as this contact is open, all of them open in the selected arrangement the common anode power source connected thyratrons are switched off.

It is therefore very important that the period during which the contact 47 is interrupted, is kept as short as possible. But if you have this time very much briefly, it could happen that contact is re-established before complete deionization has taken place in the thyratron which has been made conductive Has.

In this case, as soon as contact 47 would be closed again becomes, the thyratron conducts again, and the contact 47 would be broken again, so that the relay could not come to rest, but would rattle. To do this too prevent, the high-resistance resistor 41 is connected in front of the thyratron grid, which prevents the grid of the thyratron when the contact 47 closes immediately again receives a sufficiently high bias to make the thyratron conductive again close.

In the exemplary embodiment dealt with here, the situation is as follows chosen that the period during which the voltage of the supply apparatus is interrupted as soon as a slub is connected to any of the central feeding equipment Box arrives, about 20 milliseconds.

Because in the case of threads of normal quality, the number of liters to be eliminated Thickening is not particularly large, a considerable number of boxes can appear this central apparatus can be connected without the risk of too many slubs pass without being intercepted.

A good thread has a thickening of about 10 km. At a speed of 600 m / min, one appears about every 15 minutes Thickening in the measuring capacitor. When using 30 measuring arrangements, which are from one Food apparatus are served, so every half minute hits a slub in one of the measuring capacitors.

Under these circumstances, on average only 0.66 0 / co of the slubs will not be intercepted. In the case of a poor quality thread, one can assume that about every 3 km a thickening appears, and in this case the percentage of would not trapped slubs will be about 0.2.

This percentage is still perfectly acceptable.

Below is a list of values for the resistors and capacitors, which have been used in the circuit: resistors capacitors 4. ....... 47 Kiloohm 9. ........... 25 pF 31 to to to to to to 27 Kiloohm 3 to to to to too to to to to to 33 pF 37. ....... 10 Megohm 32. .......... 3 à 4 pF 38. ....... 68 Kiloohm 33rd and 34th ... 120 pF 41 ........... 7 Megohm 35 .............. 220 pF 42. ....... 1 Megohm 36. ........... 10 39 zuzuzuzuzuzuzuzuzuzu20 pF 40 ..................... ..... 10nF Wash 6. Fifteen turns with an inner diameter of 7.5 mm. The wire used was: enamel wire of 0.6 mm. The tapping of the coil 6 is chosen so that between the anode and taps nine and six turns lie between the tap and the grid.

8. Nine turns with an inner end diameter of 6 mm, wire diameter of 0.6 mm. The working frequency in this case was 52 Mc. The relay coil 45 has a resistor of 500 ohms, and capacitor 46 has a capacity of 4 microfarads. As a rectifier Metal rectifiers were used in all rectifier circuits. The currents in tubes I and 1a were approximated to or

I, I mA and 0.75 mA at an anode power source voltage of 100 Volt. The anode voltage of the thyratron was about 150 volts and the negative bias voltage of the grid about 6 volts.

Claims (7)

PATENT CLAIMS: I. Device for controlling the thickness of textile threads, in which the thread inj is known per se between the electrodes of an electrical Condenser is passed through and caused by the deviations of the threads Changes in capacitance converted into current or voltage changes by suitable means are characterized in that the capacitor is in. A branch of a tube generator circuit is included, the reactance of the capacitor increasing the power generated determined or at least partly determined, and that the high-frequency vibrations generated with the help of a detector whose output circuit is connected to a relay circuit to which the rectified voltages are fed as pulses, rectified will. 2. Apparatus according to claim I, characterized in that the generator circuit contains a negative feedback in addition to a positive feedback. 3. Apparatus according to claim 2, characterized in that the positive Feedback is considerably larger than necessary to generate vibrations, and is fully or largely offset by the negative feedback. 4. Apparatus according to claim 2 or 3, characterized in that the negative feedback line from a resonant circuit connected as a blocking circuit is formed, which is received in the cathode lead. 5. Apparatus according to claim 2 or 3, characterized in that the negative feedback line is formed by a potentiometer circuit, the measuring capacitor forming part of this potentiometer. 6. Apparatus according to claim 1, 2 or 3, characterized in that that a capacitor is connected in series with the grid of the generator tube, the is bridged by a leakage resistance, and that the grid has a high ohmic resistance is connected in series with a capacitor with the cathode, the latter capacitor being connected to the input line of a relay stands. 7. Device according to claims I to 6, characterized in that that the relay is connected to the anode circuit of a thyratron, its grid is connected to the output line of the detector, which determines the amplitude changes, that occur in the generator circuit is converted into low-frequency voltage changes.