CS256706B1 - Electronic circuit for looms' control system's function checking - Google Patents

Abstract

The connection of the electronic elements according to the invention relates to the field of control and monitoring systems of weaving looms and solves the electronic circuit for checking the function of the weaving loom control system. The essence of the connection is an indication of the presence of a control signal emitted by the control system in each turn of the main shaft of the weaving loops. In the absence of a control signal at a defined time interval, the circuit stops the weaving loops and signals a fault. The connection can also be used to check the position sensors function, which define the time slots for certain technological and control operations on the weaving loom.

Description

The invention relates to the wiring of an electronic circuit for checking the function of a weave control system, which allows continuous control of the function of a weave control system during weaving, and in the event of a failure of the control system circuits ensures stopping of the weave with simultaneous fault indication thereby enabling high quality fabric production.

Modern weaving looms are equipped with a control system that monitors the course of the entire weaving cycle from the textile-technical point of view, which means that at each revolution of the main spindle the weft threads follow the warp threads, warp thread continuity reinforcements at a given location and the exact position of the main shaft by means of a weft stop. However, in the event of a failure in the control system circuits, the entire weaving cycle remains uncontrolled, which in the absence of the operator can result in the production of poor fabric, thus also the loss of textile material and overall economic losses.

The above-mentioned deficiency removes the electronic circuit for checking the function of the weave control system of the invention, which is based on the evaluation of the presence of a control signal transmitted by the control system at each turn of the main shaft. The control signal as an intermediate product of the control system is always available. In the event that the control circuit detects the absence of a control signal within the prescribed time interval, by means of a blocking relay at its output, it stops the circuits and signals a fault. The control circuit consists of a dual-input NAND gate, a monostable flip-flop, an inverter, a molding circuit, a three-input NAND gate, a two-input AND gate that controls a transistor in a collector having a blocking relay with a protective diode. logic circuit Y - A. B and a delay line formed by resistors and capacitors.

FIG. 1 shows an example of an electronic circuit for controlling the function of a weaving control system, wherein the signal input 110 is connected to the input 11 of the NAND gate 10, the output 14 of which is connected to the input 21 of the monostable flip-flop 20. of monostable flip-flop 50 and at the same time to input 31 of negator 30, at output 34 of which is connected input 41 of monostable flip-flop 40. Its output 44 is connected to adjusting input 51 of flip-flop 50 of R-S type to output 54 connected input 62 a NAND-type gate 60, the second gate 61 of the gate 60 coupled to the AND gate 70 input 70 at the same time forming a signal input 111, while the gate 60 output 64 is connected to the gate 70 input 72 and the gate gate 80 NAND, which is further coupled to input 91 of the Y = A combination logic circuit 90. B and via a resistor 103 connected to the gate input 12. At the same time, a capacitor 104 is connected to the gate input 12, which is connected to a common conductor by the other, the other gate input 63 being connected to the gate output 84. The gate 80 is coupled to the input 92 of the logic circuit 90 and at the same time serves as a signal input 112 to which one outlet of the capacitor 102 is simultaneously connected with the other outlet entering the input 22 of the monostable flip-flop 20.

The output 74 of the gate 70 is connected via a resistor 106 to the base of the transistor 100, in which a blocking relay 101 with a protective diode 105 is connected in the collector circuit. The output 94 of the logic circuit 90 is connected to the signal output 113.

The initial state of the electronic circuit for checking the function of the weave control system is characterized by the following logical levels of inputs and outputs.

At input 11 of gate 10 there is level L of signal input 110. At input 61 of gate 60 and at input 71 of gate 70 is of signal input 111 of level L. At input 81 of gate 80 and at input 92 of combinational logic 90 is from signal input 112 level H. At the output 54 of the monostable flip-flop 50, and hence at the gate 62 input, there is a level H. At the gate output 64 there is a level H, which is also at gate 70 input 72 and gate 80 input 82, input 91 the logic circuit 90 and the gate input 12. At the gate output 84 and thus at the gate input 63 there is a level L. The gate output 74 has a level L, the transistor 100 is open, a blocking relay. the voltage to the circuits of the cross coupling is open and the output 94 of the logic circuit 90 controlling the light signaling 113 through the signal output 113 is level L.

When the crosses are set to WOVEN mode, the control system sets the H level on the signal input 111 (LOCK signal, so the transistor 100 closes and the relay 101 energizes the clutch circuits. This H level at the gate input 61 does not affect the H level of its output 64 63 is at L level. When the main drive and clutch motor is turned on, the control system sets L level (MACHINE RUN signal) at signal input 112, which sets gate 84 through inputs 81 and thus gate 60 input 63 to level H. The MACHINE RUN signal edge across the capacitor 102 simultaneously triggers the monostable flip-flop 20 with a tens of microseconds time constant.The level L from the monostable flip-flop 20 output 24 applied to the monostable flip-flop 50 neutral input 52 does not affect the H level at its output 54, The MACHINE RUN signal passes output 64 of the SB gate to L level, thereby arriving e to change the output level 74 of the gate 70 to L, so that the transistor 100 opens. This condition lasts during the oscillation time of the monostable flip-flop 20, which is several times shorter than the anchor time of the relay 101, so that this remains in the closed state. The signal tulle from the monostable flip-flop 20 via the negator 20, the shaping circuit 40, and through the adjusting input 51 of the monostable flip-flop 50 changes the state of its output 54 to L, so that the gate output 64 reaches the H level. its output 74 to level H, whereby the transistor 100 closes and remains closed during the oscillation of the monostable flip-flop 50, which must be longer than the duration of one revolution of the main weave shaft.

If signal level 110 (CONTROL SIGNAL) and gate 11 input 11 receive an H-level signal before the pivoting time of the monostable flip-flop 50, the monostable flip-flop 20 is triggered again, which via the reset input 52 of the monostable flip-flop 50 sets its output 54 to H, thereby temporarily switching off transistor 100 without dropping the anchor of the latch relay 101. After the pivoting time of the monostable flip-flop 20, the output 54 of the monostable flip-flop 50 is set to L so that transistor 100 again switches on and remains switched on during the swing time of the monostable flip-flop 50.

In the event that the CONTROL SIGNAL at the signal input 110 does not reach, the output 54 returns to the H level after the swiveling time of the mono-fixed flip-flop 50, through the gate 62 input 60 to set its output 64 to L. Level L from gate output 64 through resistor 103 at gate input 12 closes the signal path from signal input 110 so that the monostable flip-flop 20 cannot be triggered again, thereby setting the monostable flip-flop 50, leaving the transistor 100 permanently open. When the armature of the interlock relay 101 drops, the clutch opens, causing the MACHINE RUN signal level at signal input 112 to level H. This level at input 92 of logic circuit 90, along with level L at its input 91, sets output 94 to level

H. The logic circuit 90 ensures that the signal output 113 for controlling the malfunction indicator light is blocked during a short-term trip of the transistor 100 and is only active after the clutch is disengaged.

The RC element, composed of a resistor 103 and a capacitor 104, provides the necessary length of the input signal for proper operation of the monostable flip-flop 20.

The described electronic circuit can be used for all types of weaving cloths equipped with a control system.

Its novelty, compared to the prior art solution, is that in the event of a failure in the control system circuits, it ensures the shutdown of the weaving looms from operation, thus preventing the weaving of poor quality material.

The described electronic circuit in the proposed arrangement can also be used to check the correct functioning of the inductive position sensors of the main shaft of the weaving loops used to define the time space for weft range control, the output signal from the inductive sensor being applied to the signal input 110.

SUBJECT

Claims (2)

SUBJECT An electronic circuit for monitoring the function of the weaving control system, characterized in that the signal input (110) is connected to an input (11i) of the gate (10) whose output (14) is connected to the input (21) of the monostable flip-flop (20). whose output (24) is connected to the reset input (52) of the monostable flip-flop (50] and simultaneously to the input (31) of the negator (30), the output (34) of which is connected to the input (41) of the monostable flip-flop (40) the output (44) of which is connected to the adjusting input (51) of the R-S flip-flop circuit (50), to the output (54) of which the gate (60) input (62) is connected, 60) coupled to the parallel input (71) at the same time forming a signal input (111) while the output (64) of the gate (60) is coupled to the input (72) of the gate (70) and simultaneously to the gate input (82). 80), which is further coupled to the input (91) of the logic circuit (90) and via the resistor (103) of the spo connected to the gate input (12) to which a capacitor (104) is connected in one field to the other The other input (63) of the gate (60) is connected to the output (84) of the gate (80), the input (81) of which is connected to the input (92) of the logic circuit (90). and at the same time serves as a signal input (112) to which is also connected one terminal of the capacitor (102) with the other terminal entering the input (22) of the mono8 stable flip-flop (20), while the output (74) of the gate (70) via a resistor (106) connected to the base of a transistor (100) in which a blocking relay (101) with a protective diode (105) is connected, the output (94) of the logic circuit (90) being connected to a signal output (113). 1 sheet of drawings