CS213199B1 - Connection for automatic control of impulses of the length counter - Google Patents

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention

In metallurgical plants, the length counters used to adjust the length of the part to be cut as a pipe or profiled rods, sheet metal and the like are controlled by pulses which supply rotary pulse generators connected to the pickup plate or cylinder for these length counters. . The disappearance of these pulses due to mechanical or electrical failure usually results in an accident, for example when the product comes out of the rolling mill. In doing so, there is also the danger of injury, breakdown and thus economic damage. There are known mechanical systems for controlling the product coming out of the rolling mill. These are. however, in metallurgical operations unreliable. There are also known control electronic pulse circuits with timers and logic, but they are complicated and expensive.

The above-mentioned disadvantages of the prior art are eliminated by a circuit for automatic pulse control of the pulse counter consisting of an astable flip-flop, counter, gates, memory, negator, boost stage and fault relay according to the invention. a forming circuit input whose output is coupled to a first reset counter of the control counter, the counter input of the control counter is coupled to the output of the clock pulse blocking circuit, the input of which is coupled to the astable flip-flop output and the clock pulse blocking circuit input of direct output of the shaping voltage circuit,

213 199 whose reset input is coupled to the L level via the idle control relay delayed release timing relay contact, and the shape memory circuit input input is coupled to the L-level delayed control relay delayed output contact, where the second control counter resetting input is connected. with a direct output of the memory memory circuit, whose reset input is coupled to the L level via the normally closed contact of the fault reset button, and the insertion memory input of the shaping memory circuit is connected to the L-level contact. where the output of the fourth bit of the control counter output word is connected via a negator to the input of the fault memory, the direct output of the fault memory being connected to the input of the power stage whose output is e is connected to one side of the fault relay coil and wherein the other side of the fault relay coil is connected to the positive potential terminal, wherein a quenching diode is connected in parallel to the fault relay coil.

The advantage of the circuitry for automatic pulse control of the length counter according to the invention is its relatively great simplicity and low cost. Its advantage is furthermore its considerable reliability. Its further advantage is that, when connected to its input, a non-contact, magnetic field-controlled switch placed against a magnet mounted on a rotating shaft serves as a wiring to control the rotation of the monitored shafts and machines without further modification. Another advantage is that the purchase and maintenance requirements and the mounting space required are relatively small.

The circuit for automatic pulse counter pulse monitoring is illustrated by way of example in the accompanying drawing, showing a block diagram of an exemplary embodiment.

The circuit for automatic checking of the pulses of the length counter according to the exemplary embodiment consists of an astable flip-flop 2 whose output is connected to the input h of the clock circuit 6 of the counter-clock circuit. The second blocking input i of this clock circuit 6 is connected to the direct output m of the shaping memory circuit 4. The input input 1 of this shaping memory circuit 4 is connected to the D level via the work contact 5a of the delayed release of the control circuit. The reset input to this shaping memory circuit 4 is also connected to level 1 via the normally closed contact 5b of the delayed release of the control circuit after starting the track. The output i of the clock circuit 6 is coupled to the counting input c of the control counter 2. The input A of the monitored pulses is connected via the shaping circuit 1 to the reset input. The second reset input 2 of this control counter 2 is coupled to the direct output 4 of the shaping memory circuit 6. The input input of this shaping memory circuit 8 is connected to the L-level via the fault contact button 8a of the fault button.

The output d of the fourth bit of the output word of the check counter 2 is connected via the negator 13 to the input input f of the fault memory 6. The output 8 of the fault memory 8 is connected via power stage 10 to one side of the coil 11 of the fault relay. The other side of the fault relay coil 11 is coupled to the + U terminal of the positive potential. A quench diode 12 is connected in parallel to the coil 11 of the pore relay 199. The negated output 6 of the shaping memory circuit 8 is coupled to the reset input e of the fault memory 2.

In operation, after a set delay, the normally open contact 5b of the delayed release control relay opens and disconnects the L level from the reset input to the shaping memory circuit 4. At the same time, the working contact 5a of the same timing relay connects the L level to the input input 1 of the shaping memory circuit. the output m of the shaping memory circuit 4 tim goes to state H. This state H is applied to the blocking input i of the gating circuit 6 for blocking the clock pulses. Thereby, the gating circuit 6, the clock pulse blocking is released, and the pulses from the astable flip-flop applied to the input h of the clock-pulse blocking circuit 6 can pass through and are available in its negated form at its output 6. Since this clock pulse blocking circuit 6 is coupled to the counting input 6 of the decimal counter 2 operating in the BCD code, it is counted from state 0 to state 9. If the monitored pulses from the pulse generator are present, they are applied also via input A and shaping circuit 2 to the first reset input and control counter 2, and this is reset in state 4 by the first pulse L-H. If due to mechanical or electrical failure, the monitored pulses for the length counter disappear, control counter 2 is not timely is reset and is counted up to 8.

In this state, the output d of the fourth bit of the output word of the check counter 2 goes to the state H. After negation in the negator 15, the signal L is applied to the input input f of the fault memory 2 (R-S). Its direct output tím thus goes to state H. This state, applied to the input of power stage 10, causes its output to switch to the zero potential OV and this is connected to the first supply of the coil 11 of the fault relay. it can close and can switch off the monitored rolling mill with its contacts in time and thus prevent the accident by moving the metallurgical product out of it. At the same time, this fault relay can switch on the fault warning. After the fault in the pulse generator circuit has been eliminated, the normally open contact 8b is opened and the level L is disconnected from the null input n of the shaping memory circuit 8 by pressing the fault reset button. At the same time, the work contact 8a connects the level L to the input input 6 of the shaping memory circuit 2A - S / NAND. Thus, its direct output výstup goes to state H, which is applied to the second reset input b of the control counter 2, resetting it to state 0. The output d of the fourth bit of the output word of the control counter 2 is then switched to state L. Now the signal H. is applied to the input input f of the fault memory 2 of the NAND (RS). At the same time, the negated output 6 of the shaping memory circuit 2 has switched to the state L ”. This, applied to the reset input e of the fault memory 2, causes its direct output g to go to the level L. Timing of the fault relay coil 11 is switched off via power stage 10. The control circuit is ready for operation again.

Claims (1)

OBJECT OF THE INVENTION Circuit for automatic length counter pulse control, consisting of an astable gate counter flip-flop, memory, negator, boost stage and fault relay, characterized in that the input (A) of the monitored pulses is connected to the input of the forming circuit 213 189 (1), the output of which is connected to the first reset input (a) of the control counter (2), wherein the counter counters (c) of the control counter (2) are connected to the output (j) of the clock circuit (6). the input (h) of which is coupled to the output of the flip-flop (3) and the input (i) of the clock pulse blocking circuit (6) is coupled to the direct output (m) of the forming memory circuit (4) via the normally closed contact (5b) of the delayed release of the control circuit and connected to the ^M L level, and at the same time the input input (1) of the shaping memory circuit (4) is coupled via the operational contact (5a) of the delayed release of the control circuit with the second reset vatup (b) of the control counter (2) is coupled to the direct output (q) of the form-shaped parallel circuit (7) whose reset vetup (n) Js via the idle contact (Sb) of the odeta button The fault input is coupled to the L level and the insertion input (o) of the shaping memory circuit (7) is connected via the work contact (8a) to the L level, the negated output (p) of the shaping memory circuit (7) being connected to the reset input. e) a fault memory (9), further comprising outputting (d) the fourth bit of the output word of the control counter (2) via a negator (13) connected to the ee stringing input (f) of the fault memory (9); 9) faults It is connected by the input of power stage (10), whose output is connected by one side of the fault relay coil (11) and where the other side of the fault relay coil (11) is connected to the positive potential terminal (+ U). olvoe (11) fault relay is connected crashed diode (12). 1 drawing