CS236722B1 - Periodic motor starter wiring - Google Patents

Abstract

The invention relates to a controller for periodic starting of a pump motor at a wastewater treatment plant in a cycle and time determined by the treatment technology, with the starting cycle being selectable up to 160 hours. The essence of the invention is a time pulse counter with the possibility of selecting the number of pulses and thus the duration of starting - running - the pump and at the same time the duration of its standstill, with the control output triac being open for the duration of the pump running, which turns on the pump motor.

Description

The invention relates to the connection of a periodic pump motor starter at a sewage treatment plant in a cycle and time determined by the purification technology. The start cycle is selectable up to 60 hours.

Wastewater treatment technology requires the pump motors to be started for a relatively short time, but at relatively long breaks. The entire cycle of chemical and biochemical treatment plants can take tens of hours, so the pumps in these plants are started according to the prescribed schedule. Obviously, keeping the schedule depends on the reliability and diligence of the operating staff. It is therefore desirable to ensure that the pumps are switched on at such long intervals by means of an electrical circuit consisting of mechanical timing relays driven by synchronous motors.

Their disadvantage, however, is that they operate at maximum times of up to 24 hours, so that in order to achieve a longer time interval, several such relays must be coupled in succession.

A further disadvantage is that the assembled device is relatively large and occupies a large space. Also, eventual adjustment of the length of the time interval, for example when changing the operating conditions of the treatment plant, is not quite simple.

These disadvantages are eliminated by the wiring of the periodic motor starter according to the invention, characterized in that the outputs of consecutive decade counters of which the counter decade input of the first decade is connected via a two-inlet throat to the output of the time pulse generator are connected via output switches and decade inverters, in pairs first, second and third, fourth, to the inputs of two decade gates, the outputs of which are connected via derivation circuits inverters, differentiation circuits and summation diodes to the synchronization input D of the circuit, the output from the first decade gate to the setting input D output of the second decade gate to one input of the output gate when its second input is connected to the negative output of the D circuit and the output both through the output inverter and output amplifier to the control electrode of the control triac and simultaneously through d the erivating reset amplifier to all the decade reset inputs of the counter decades, while the first anode of the triac control is grounded and the second is connected either directly through the starter motor winding or via the auxiliary contactor coil to the supply / mains. (

An exemplary circuit of a periodic motor starter is shown in FIG. 1. Here, a counter input of the first of four consecutive decades of counters £, £, £, 2 is connected to the output of the time pulse generator 6 via a two-input starter gate. it is connected to the trigger input £. Pairs of inputs of two decade gates 28. 29 are connected to outputs of individual decades via output switches 14. 15. 16. 17 and decade inverters 25. 26. 21. 28, always so that to the outputs of the first £ β of the second £ decade, the first decade gate 28 and the outputs of the third 6 and the fourth decade by the inputs of the decade gate 2 £.

The outputs of the decade gates 28, 12 are further coupled to the synchronization input D of the circuit 8 and the output from the decade gate 28 to the adjusting input D of the circuit, via the inverters 52, 11 of the differentiating circuits, the differentiating circuits 30, 31. 8 and on the other hand the output from the second decade gate 29 to one of the inlet gate 16.

The second output of the output gate 36 is connected to the negative output D of the circuit 6 and the output via the output inverter 43 and the output amplifier 10 to the trigger electrode of the control triac 16. At the same time, the output of the output gate 36 is also connected via a differentiating reset amplifier 2 to all the reset inputs of the decades 6, 6, 6 of the counter. The first anode of the control triac 11 is grounded and the coil of the control motor contactor 12 or the coil of the controlled motor 13 is connected directly to the second.

The circuit works as follows: With a ON voltage - command to operate - at the trigger input 2, time pulses start to pass through the trigger gate 6, for example with an interval of 1 minute, from the time pulse generator 6 to the counter input of the first decade.

These pulses pass after the lower decade is filled into the counter inputs of the higher decades.

According to switch settings 14. Ji, Ji, 1? at the same time there are zero pulses at the selected outputs of the pairs of decades 6, 2 and 6, Z, which are respective decade inverters 2 *. 25 and 26. 27, also zero pulses appear at the outputs of the respective decade gates 28. 29. This also transmits a zero pulse from the first decade gate 28 to the setting input D of the circuit 8. At the same time, however, the pulse is the first «inverter 32» the circuit is converted to one in the first derivative circuit .30 and then transferred as a positive narrow pulse through the first summing diode 34 to the synchronization input D of the circuit 8. With this synchronization pulse the D circuit is set according to its current state at its setting input. where the state is just zero. A zero state is also set at the positive output D of the circuit 8 and hence at one input of the output gate 36.

However, the output gate 36 will remain closed until there are also one pulses at both inputs of the second decade gate 32, i.e., when zero pulses are present at the decade switches 16, 17 of the selected outputs of the third and fourth decades 6, 1 of the counter. At this point, there will also be one pulse at the output of the second inverter 33 of the differentiator circuit and thus at the second input of the output gate 36.

At the same time, however, the leading edge of the positive pulse and the output of the second derivative inverter 33 to the synchronization input D of the circuit 8 are transmitted via the second derivative circuit 31 and the second summing diode 35. at the output of the first decade gate 28 and hence at the setting input D of the circuit 8, one level is set, the positive output D of the circuit 8 and the first input of the output gate 36 are also set to one.

There will then be a zero pulse at the output of the output gate 36. This zero pulse is turned by the output inverter 43 to one, transmitted by the output amplifier 10, to the control electrode of the control triac 11, which is then brought into a conductive state. This condition lasts until it reappears at the selected outputs of the first and second decades at the same time, which are transmitted as a zero pulse to the setting input D of the circuit 8 and simultaneously to its synchronizing input, thereby resetting the positive output D of the circuit 8 to zero. level. Thus, the output gate 36 closes ^at the output of which the one pulse appears and thus, after passing through the output inverter 33, the output amplifier 10 closes as a zero control triac 11. it resets all the decades 8, 2, Z so that by the following time pulse from the time pulse generator J, they start to read again from the beginning.

As a result of the operation of the entire circuit, pulses remain from the beginning until the pulses of the selected outputs at the switch J6 simultaneously appear on the switch J6.

At this point, it is brought into a conductive state and remains so until the pulses from the output switches 15, 15 appear again simultaneously. When this happens, all decades of the counter are reset, control triac 11 closes, and the process repeats. The triac control 1ak thus switches the pump motor 13 either directly or via a contactor 12. Thus, if pulses are transmitted from the time pulse generator J after, for example, one minute, it is then possible to select an engine start time in the range of 1 minute to 99 minutes and a rest period in the range of 100 to 10,000 minutes.

Of course, the circuit can also be used to temporarily control other appliances, such as heating, and that by selecting a different clock frequency, or by using a pulse generator with a choice of its frequency, it can further expand its use.

Claims (1)

Connection of a periodic motor starter characterized in that the outputs of consecutive decades (4, 5, 6, 7) of the counter, whose counter input of the first decade (4) is connected via a two-input trigger gate (3) to the output of the time generator (1) pulses are connected via output switches (14, 15, 16, 17) and decade inverters (24, 25, 26, 27) in pairs first, second and third, fourth to inputs of two decade gates (28, 29), whose the outputs are connected via derivation circuit inverters (32, 33), differentiation circuits (30, 31) and summation diodes (34, 35) to the synchronization input D of the circuit (8), the output of the first decade gate (28) to the adjusting input D circuit (8), the output of the second decade gate (29) being also connected to one input of the output gate (36), the other input of which is connected to the negative output of the D circuit (8) and whose output is connected via the output an inverter (43) and an output amplifier (10) for the control electrode of the control triac (11) and, on the other hand, via a derivative zero amplifier (9) to the zero inputs of the decade (4, 5, 6, 7) counters, ) is grounded and the other is connected either directly through the winding of the motor to be started (13) or via the coil of the auxiliary contactor (12) to the mains supply (44).