EP0090766A1 - Electronic testing apparatus for monitoring a plurality of running-yarn positions in textile machines - Google Patents

Abstract

The electronic interrogation device is used to monitor a large number of thread running points on a textile machine, a measuring head (Ml to Mn) for determining a thread break, a bistable control means (Fl to Fn) and a switching means (Sl to Sn) being arranged at each thread running point. A clock generator (CL) acts on the clock inputs (Cl to Cn) of the control means (Fl to Fn) connected in series, which interrogate the measuring heads (Ml to Mn) in cyclical order via the switching means (Sl to Sn). The signals from the measuring heads (Ml to Mn) obtained during polling are fed via a signal line (SL) and a clock-controlled gate (Al) to a counting circuit (JS), which indicates the associated thread runner in the event of a thread break.

Description

The invention relates to an electronic interrogation device for monitoring a large number of thread running points on a textile machine, a measuring head being provided for each thread running point to determine a thread break.

The CH PS 601 093 and DE - AS 27 31 019 known. Here, the probe is guided on a guide rail along the workplaces by means of a drawstring.

It is also known from DE-AS 23 15 328 to monitor the threads running from a plurality of spinnerets for errors on a spinning machine, these errors being detected by capacitive probes and the error signals being temporarily stored. The probes and the individual memories are interrogated periodically, the error signals occurring in the interrogation pauses exceeding a threshold value being stored until the next interrogation period.

The invention has for its object to provide an electronic interrogation device that without mecha African devices and works without a probe running along the measuring points and in which no temporary storage of error signals, in this case thread break signals, is required.

This object is achieved by the features characterized in claim 1. In addition, the interrogation device can also have the features of claims 2-5.

• Fig. 1 ein Schaltbild einer Abfrageeinrichtung für n=6 Fadenlaufstellen;
• Fig. 2 ein Signalschema zur Erläuterung der Arbeitsweise der in Fig. 1 dargestellten Abfrageeinrichtung
• Fig. 3 eine Zählstufe zur individuellen Zählung der an den einzelnen Fadenlaufstellen eintretenden Fadenbrüche;
• Fig. 4 ein Signalschema zu der in Fig. 3 dargestellten Zählstufe;
• Fig. 5 eine Anzeigestufe zur Anzeige einer Fadenlaufstelle, an der ein Fadenbruch eingetreten ist; und
• Fig. 6 und 7 je eine andere Ausführung der Schalter Sl bis Sn aus Fig. 1.

The query device according to the invention is explained below, for example, with reference to the accompanying drawing. It shows

• 1 shows a circuit diagram of an interrogation device for n = 6 thread running points;
• Fig. 2 is a signal diagram for explaining the operation of the interrogation device shown in Fig. 1
• 3 shows a counting stage for individual counting of the thread breaks occurring at the individual thread running points;
• FIG. 4 shows a signal diagram for the counting stage shown in FIG. 3;
• FIG. 5 shows a display stage for displaying a thread runner at which a thread break has occurred; and
• 6 and 7 each have a different design of the switches S1 to Sn from FIG. 1.

With the circuit arrangements described below and shown in FIGS. 1, 3 and 5, a large number of several hundred thread running points can be monitored. For the sake of simplicity, the number of thread running points is assumed to be n = 6 in the figures.

1, a measuring head M1 to Mn is arranged at each thread run point, for example a ring spinning machine or a flyer. This provides an analog thread running signal as long as the thread is running at the relevant running point. The thread running signal then has a positive value up to, for example, +5 V and becomes zero if the thread breaks or the thread stops.

By limiting the thread running signal is transformed into a dual signal of the value H or L.

Parallel to the measuring heads Ml to Mn, a series connection of n bistable control means Fl to Fn is provided, each of which is assigned to one of the measuring heads. The outputs of each measuring head, such as Ml, and the associated bistable control means, such as Fl, are connected to the two inputs of a switching device, for example an electronic switch, such as S1. The output of each switch S1 to Sn is connected to a common signal line SL. The switches Sl to Sn can also be replaced with the aid of an AND gate Gl to Gn and a diode Dl to Dn, as shown in FIG. 6. There are also other arrangements possible which the perform the same function; for example a resistor Rl to Rn with two diodes Dl to Dn, and dl to dn (Fig. 7).

For the purpose of interrogating the individual measuring heads Ml to Mn, a clock generator CL is provided, which controls the clock inputs Cl to Cn of the bistable control means Fl to Fn via a clock line C. The clock generator CL preferably delivers pulses of a high repetition frequency in the range of several kHz, for example 10 kHz. But you can also work very slowly, for example at 10 Hz.

A first AND gate A1 with a negated and a non-negated input forms the output stage of the interrogation device. The negated input is connected to the signal line SL, the other input to the clock line C. The output line or display line of the first AND gate Al is designated A.

A second AND gate A2 with a negated input and a bistable control means F7 with a negated output Q connected in series with this AND gate A2 form a starting circuit. A reset AND gate A3 with a negated input is also provided.

The negated inputs of the AND gates A2 and A3 are Eiv _f - connected to the clock line C. The other gear of the AND gate A2 or A3 is connected to the output of the first bistable control means Fl or the nth bistable control means Fn. The negated one Output Q of the bistable control means F7 controls the data input E1 of the first bistable control means Fl, while the output of the reset AND gate A3 is connected to the reset input of the bistable control means F7. The output line of the reset AND gate A3 is denoted by R.

A switching stage SS is connected to the display line A, which switches off the machine or only the affected thread runner if a thread break occurs. An indicator stage JS is connected to lines A, C and R, as will be described in more detail in connection with FIGS. 3 and 4.

The mode of operation of the interrogation device described will now be explained with reference to FIG. 2.

Here C and C mean the series of clock pulses or negated clock pulses, Fl to Fn the output signals of the bistable control means Fl to Fn; the other output signals are identified by the same designation as the switching elements producing them or the lines assigned to them.

All logical switching elements shown in FIG. 1 and the clock generator CL are intended to carry dual H signals or L signals at their outputs. At the beginning, all bistable control means Fl to Fn should be in the idle state, that is to say carry an L output signal; the output signal Q of the bistable control means F7 is then an H signal.

The first bistable control means F1 is set by a start pulse Q = H and the first clock pulse C and reset by the second clock pulse. As a result, the following bistable control means F2 etc. to Fn are set and reset in each case during the period of a clock pulse C.

It is assumed that the measuring heads Ml, M3 to Mn generate a thread running signal of a positive value, while the measuring head M2 delivers a signal of zero value due to thread breakage. In Fig. 2 only the signals Fl, F2, Fn and Sl, S2, Sn are shown. All F signals are only shifted by one clock; in the case of the S signals, the signal S2 fails, while all the other S signals are simultaneous with the corresponding F signals.

The signal line SL now carries the sum of all S signals; that is, the sum signal is an H signal for the duration of all S signals with the exception of signal S2; during the duration of this signal, the sum signal on the signal line SL has the value L. The logical addition of the negated sum signal SL and the clock pulse in the AND gate A1 provides the output signal A; this has the value L when all measuring heads Ml, M3 to Mn are interrogated with the thread running intact, but has the value H when the measuring head M2 is interrogated with defective thread.

The last four lines of FIG. 2 relate to those in the starting circuit A2, F7 and in the resetting circuit A3 formed impulses. Row C of the inverted clock pulses is also shown here, which are decisive for the clock control of these circuits.

The output signal on the display line A can be processed in an active stage SS or JS, FIG. 1, in various ways. It can be used in a known manner to switch off the machine or the thread run point at which a thread break has occurred by means of a switching stage SS. Indicator levels JS for displaying or counting thread breaks are to be explained with reference to FIGS. 3 and 5.

3 shows, as the first embodiment of the indicator circuit JS, a counting stage which registers the thread breaks occurring on the individual measuring heads Ml to Mn in separate counters Zl to Zn. This indicator circle can be used advantageously on ring spinning machines.

This counter stage contains an n-digit shift register SR with a data input connected to the display line A and a shift input which is connected to the clock line C with the interposition of a delay element V. A reset input of the shift register SR is connected to the reset line R.

The outputs of the individual cells of the shift register SR are each connected via an AND gate to a counter Zl to Zn; a second input of each AND gate is connected to a count line ZL which appears at the end of each polling cycle. This counts the H signal contained in a cell in the event of a thread break into the associated counter, in the present case Z2. At the end of each polling cycle, the shift register SR is reset by a reset pulse on line R. The order of the counters Zl to Zn is from the back to the front, since the signal on the display line A, which is assigned to the first thread monitor, appears in the rearmost cell of the shift register SR at the time of the counting pulse ZL.

So that a thread break cannot be counted more than once, when an H signal occurs on the display line A, the associated spinning position must be stopped via the switching stage SS, FIG. 1; Furthermore, the counting must be interrupted, for example, by opening a switching means (not shown) arranged in the clock line. After the thread break has been eliminated, the spinning position and the counting are started again by hand.

FIG. 4 again shows the signal on the display line A from FIG. 1 and the delayed clock pulse V in the first line.

Due to its rising flanks marked with a dash, the value of the display signal A which occurs at the same time is inserted into the shift register SR; this is the value H of signal A that occurs simultaneously with the second clock pulse.

FIG. 5 shows a simple indicator circuit for displaying a thread running point at which a thread break has occurred. As long as there is an L signal on the display line A, that is to say there is no thread breakage, the bistable control means F8 is in the idle state, that is to say carries an L signal at its output. In this case, the clock pulses on the clock line C can pass the AND gate A5 via its negated input; they are counted into the counter Z as numbers 1 to n in each polling cycle. The bistable control means F8 is set by a thread break and the H signal thus occurring on the display line A. As a result, the AND gate A5 is blocked for the clock pulses, and the counter Z stops and shows the number of the thread runner with the thread break. This number is stored in the memory SP; it can be deleted manually by pressing a key, not shown.

The indicator circuit described above is advantageously used for displaying broken fuses on a flyer.

6 shows a further possible embodiment instead of the switches S1 to Sn. These switches can be replaced by an AND gate Gl to Gn and a diode Dl to Dn. As soon as the thread monitor Ml and the bistable control means F1 each deliver an H signal to the AND gate, its output also becomes H. This H signal then goes to the signal line SL via the diode D1. The result is the same as with the switches Sl to Sn in Fig. l. The diodes Dl to Dn are used for decoupling.

Fig. 7 shows another embodiment of the switches Sl to Sn, each of which is replaced by a resistor Rl to Rn and two diodes Dl to Dn and dl to dn. As long as all measuring heads Ml ... emit an H signal with the thread running intact, an H signal is generated when queried by the bistable control means Fl ... assigned to each measuring head on the line SL. In the event of a thread break e.g. at the measuring head M2, however, this delivers an L signal which, when interrogated by the bistable control means F2, reaches the signal line SL. This effect is therefore the same as that shown for the switches S1 ..., Fig. 1, in Fig. 2.

Claims (5)

1. Electronic interrogation device for monitoring a large number of thread running points on a textile machine, a measuring head for determining a thread break being provided for each thread running point, characterized in that
that each measuring head (Ml to Mn) is assigned a bistable control means (Fl to Fn) with a data input (El to En) and a clock input (Cl to Cn), the bistable control means (Fl to Fn) being connected in series via their data inputs are and a clock generator (CL) acting on their clock inputs (Cl to Cn) is provided;
that to each measuring head (Ml to Mn) one input of a switching means (Sl to Sn) is connected, the other input of which is connected to the output of the associated bistable control means (Fl to Fn) and the output of which is connected to a common signal line (SL) is;
that an AND gate (Al) is provided with a negated input that ver with the signal line (SL) is bound and its other input is connected to the clock (CL);
that switching elements (A2, F7, A3) are provided for generating a respective start signal at the data input (E1) of the first bistable control means (F1) in a cyclic sequence,
that the output of the AND gate (A1) is connected via a display line (A) to an active device (JS, SS) which responds to a yarn break. 2. Electronic interrogation device according to claim 1, characterized in that
that the clock generator (CL) operates with a pulse frequency in the range from 5 Hz to 250 Hz. 3. Electronic interrogation device according to claim 1 or 2, characterized in that
that the switching elements (A2, F7, A3) for generating a start signal a second AND element (A2) with a negated input and a bistable control means (F7) with negated output (Q) connected to it, and a third AND element (A3) with a negated input, the negated inputs of the AND gates (A2, A3) are connected to the clock generator (CL), their other inputs are connected to the outputs of the first (Fl) or nth bistable control means (Fn), and the negated output (Q) of the seventh bistable control means (F7) to the data input (El) of the first bistable control means (Fl) and the output (R) of the third AND gate (A3) to a reset input of the seventh bistable control means (F7). 4. Electronic interrogation device according to one of claims 1 to 3, characterized in that
that a counter stage with a shift register (SR) is provided as the active device, to the parallel outputs of which the individual measuring heads (Ml to Mn) are assigned counters (Zl to Zn). 5. Electronic interrogation device according to one of claims 1 to 3, characterized in
that a display stage with a counter (Z) is provided as the knitting device, which has a number (n) of counting points corresponding to the number (n) of the measuring heads and, in the event of thread breakage on one of the measuring heads (Ml to Mn), displays its number by interrupting the counting .

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