CS229509B1 - Operation countdown - Google Patents

Abstract

The connection for counting the operation relates to the field of control technology. The purpose of the invention is the actual counting of the operation at any time. The essence of the invention lies in supplying pulses to the fourth counter through the contact of the sixth relay connected to one of the pulse counters by a switch.

Description

(54) Countdown connections

2

The connection to the countdown relates to the Regulatory Department.

The purpose of the invention is to actually deduct traffic at any time.

SUMMARY OF THE INVENTION The invention is based on providing pulses to the fourth computers via a contact of a sixth relay connected to one of the pulse counters by a switch.

The present invention relates to an automatic and cyclic readout circuit with time switch with an electromechanical computer.

The countdown of the automatic temperature control operation by the cumulative clock has the disadvantage that the state cannot be reset after the operation has ended. The last data must be remembered or written down for further operation or interruption of the mains voltage. They cannot read the actual state of operation at any time. Direct connection of the electromechanical pulse counter to the switching contact of the electronic timer relay would not provide the actual indication of operation when the device is switched on.

The above drawbacks are eliminated by a countdown circuit according to the invention, characterized in that one inlet contact of the second switch part is connected to the temperature controller, one outlet contact of the second switch part to the second outlet contact of the third switch part, the third outlet contact of the third switch part 4 of the fourth part of the switch to the break contact of one pulse counter, one and third terminal of the fourth part of the switch to the second terminal contact of this part of the switch, the third contact of the third part of the switch to the coil of the sixth relay a lead contact of this switch member, a coil of a fourth pulse counter to the break contact of the sixth relay, and a changeover contact of the sixth relay to the break contact of the third relay.

An advantage of the invention is that by connecting the coil of the sixth relay through the third contact of the third switch part to the break contact of one pulse counter, a real countdown of operation is ensured even during the time switching of the device.

In the attached drawing there is a schematic connection for reading the operation of the temperature control with time switching with an electromechanical computer.

The connection consists of a mains supply 1 connected to the switches, a switch 2 connected to the temperature controller and the switches 3 and to one relay 4, a switch 3 connected to one, the second and third pulse counters, one relay 4 connected to the second and third relays 16 17, one diode 5 connected to the switches 3, from one resistor 8 connected to one diode 5, from the other resistor 7 connected to one diode 5, from one potentiometer 8 connected to one resistor 6, from the other potentiometer 9 connected to the other a resistor 7, a third resistor 10 connected to one capacitor 12 and one relay 4, a fourth resistor 11 connected to the second capacitor 13 and one relay 4, one capacitor 12 connected to one potentiometer 8, a second capacitor 13 connected to the other potentiometer 9, from one diac 14 connected to one potentiometer 8, from the other diac 15, connected to the second potentiometer 9, from the second relay 16 connected to the first diac 14 i to the capacitor 12 and the fifth relay 28, from the third relay 17 connected to the second diac 15 i to the capacitor 12 and to the fourth relay 29, from the temperature controller 18 connected to switches 3 , a power member 19 connected to a temperature controller 18, a fourth relay 20 connected to one other pulse counters 21, 22, and switches 3, one pulse computer 21 connected to the other pulse counters 22 and switches 3, from the other pulse counter 22 connected to a third pulse counter 23 and a second diode 24, a third pulse counter 23 connected to switches 3 and a third and a fifth relay 17, 28, a second diode 24 connected to a fifth resistor 25, a fifth resistor 25 connected to a third diac 27 a third capacitor 26 connected to the fifth resistor 25 as well as a fifth relay 28, a third diac 27 connected to the fifth relay 28, fifth relay 28 connected to third pulse counters 23, four-pulse counter 29 connected to switches 3 and third pulse counters 23 to sixth relay 30, and sixth relay 30 connected to switches 3 and third to fifth relays 17, 28 .

We use the wiring according to the invention to connect the thermocouple and the slider of both the potentiometer to the set cycle values, the resistance of the measuring bridge branch and the output of the one and the other potentiometer to the set temperature values both control potentiometer adjustment potentiometer. .

In the first position of the switch 3 takes place. automatic temperature control and by switching the switch 2, one supply of network 1 is directly connected to the device. The second power supply line 1 is connected via the first closed contact of the first part of the switch 3 to the temperature controller 18 and the power element 19 and through the first closed contact of the second part of the switch 3 to the changeover contact of the third relay 17 i through the first closed contact of the fourth part of the switch 3 , one resistor 6, one potentiometer 8 and one capacitor 12 to be charged. After reaching the switching voltage of one diode 14, part of the charge of one capacitor 12 is led to the coil of the other relay 16, which is energized for a moment and energizes one relay 4 by closing the switching contact. In the first relayed contact of this relay 4, the relay is held in the next operation, and in the second relayed contact of this relay 4, a third discharge resistor 10 is connected to one capacitor 12 and the fourth discharge resistor 11 is disconnected.

With the second capacitor 13 being charged from the second capacitor 13 and through one diode 5, the second resistor 7 and the second potentiometer 9, after reaching the switching voltage of the second diac 15, a portion of the charge of the second capacitor 13 is discharged into the coil of the third relay 17. by opening the break contact, it interrupts the circuit of one relay 4 which falls off and by closing the make contact of this third relay 17, a pulse is applied via the break contact of the sixth relay 30 to the fourth pulse counters 29 which counts the period of operation. In the first relayed contact of one relay 4, the voltage supply for this relay is interrupted and in its relayed contact, the fourth discharge resistor 11 is connected to the second capacitor 13 and the third discharge resistor 10 is disconnected from the first capacitor 12, the device does not disable the switch 2. The total operating time is evident from the state of the fourth pulse counter 29.

In the second position of the switch 3, periodic cyclic regulation takes place, the pulse counters 21, 22, 23 are set to a preset pulse value. By closing the switch 2, one mains supply 1 is directly connected to the device, the other through the second closed contact of the first switch 3 to the changeover contact of the third pulse counter 23 and its break contact and the second closed contact of the third switch 3 to the temperature controller 18 and power member 19 regulation is in the upper limit of the cycle. At the same time, the second supply of the network 1 is fed via the second closed contact of the fourth part of the switch 3 to one diode 5 and the next described process is repeated. The pulse from the third relay 17 is simultaneously fed via the make and break contacts of the fourth relay 20 to one pulse counter 21, which also counts and the process repeats periodically until the number of pulses transmitted by the third relay 17 reaches the default value of one pulse counter 21 its changeover contact supplying the second power lead 1 from the break contact of the third pulse counter 23 via the changeover and switch contact of one pulse counter 21 and the other closed contact of the second switch 3 to the coil of the fourth relay 20 the relay 17 to the second pulse counters 22 and the other contact sets of the fourth relay 20 prepare the downstream control cycle through the controller 18. The timing circuits measure the times in the manner described by both the pulse counter 22 and the pulse counter. 29. When the number of pulses transmitted by the third relay 17 reaches the default value of the second pulse counter 22, its changeover contact is switched, which via a make contact brings the second mains supply 1 from the break contact of the third pulse counter 23 to the lubrication solenoid of one pulse counter.

21, which resets its number state and translates its own contact.

In the folded contact of one pulse counter 21, the coil circuit of the fourth relay 20 is broken, which drops off and switches the counting solenoid of one pulse counter 21 to the third relay 17 and ensures the connection of the described elements for the upper cycle limit. At the same time, from the switching contact of the second pulse counter 22, the second supply of the network 1 is also fed to another time circuit, where the fifth resistor 25 charges the third capacitor 26 via the diode 24, after the switching voltage of the third deacon 27 has been reached. the coils of the fifth relay 28, which momentarily excites and energizes the second supply of the network 1 to the lubricating solenoid of the second pulse counter 22, which resets its numerical state and translates the changeover contact. At the same time, the voltage pulse of the fifth relay 28 is recorded by the third pulse counter 23 as a single cycle. The other complete cycles periodically run in the same manner, and the operating time is recorded by the fourth pulse counter 29 when the number of pulses sent by the fifth relay 28 reaches the default value of the third pulse counter 23, when this translates the entire device automatically.

It is brought into a delusional state by switching off the switch 2 and resetting the numerical state by the button of the third pulse counter. The total operating time is apparent from the state of the fourth pulse counter 29. In the third position of the switch 3, the automatic temperature control takes place with the possibility of switching the device on in time. On one pulse counter 21, a default value of time pulses corresponding to the switch-on time is set. By closing the switch 2, one inlet of the network 1 is connected directly to the device and the other through the third closed contact of the first part of the switch 3 and the contacts of one pulse counter 21, the third closed contact of the third part of the switch 3 to the coil of the sixth relay 30. 29. At the same time, the second power supply is fed via the third closed contact of the fourth part of the switch 3 to one diode 5 and the transition described above is repeated until the changeover contact of one pulse counter 21 is switched. , which falls off and closes the circuit of the fourth pulse counter 29 counting from that time on. In the closed contact switch of one pulse counter 21, the second supply line of the network 1 is connected via a third on contact of the second part of the switch 3 to the temperature controller 18 and the actuator 19, which are actuated with the fourth pulse counter 29 counting operation. The individual power inputs are automatically adjusted by the temperature regulator 18 according to the control deviation via the actuator 19. The device is brought to a standstill by switching off the switch 2.

In the fourth position of the switch 3, automatic temperature control takes place with the option of switching off the time. A default pulse time value corresponding to the off time is set on One Pulse 21 computer. By switching on the switch 2, one network connection is connected directly to the device and the other via the fourth closed contact of the first switch 3 and the contacts of one pulse counter 21 and the fourth closed contact of the second switch 3 to the temperature controller 18 and actuator 19; ensure automatic regulation. At the same time, this second supply of network 1 is transferred via the fourth closed contact of the fourth part of the switch 3 to one diode 5, actuating the timing circuit in the manner described, its time pulses being recorded by a pulse counter 29 recording operation. After the preset time has been reached by one switch 21, its contact is switched, which interrupts the second supply of the network 1 to the temperature controller 18 and the power element 19 and the time circuit, thus disabling the device from further operation. The unit is switched off by switching off the switch

2.

The circuitry of the invention may also be used to select control of other automation devices.

Claims (1)

SUBJECT The countdown circuit is characterized in that one inlet contact of the second switch part (3) is connected to the temperature controller (18), one outlet contact of the second switch part (3) is connected to the second terminal contact of the third switch part (3), the third the third contact of the third part and the fourth terminal of the fourth part of the switch (3) are connected to the break contact of one pulse counter (21), the first and third terminal contacts of the fourth part of the switch (3) are connected to the second terminal contact of this part of the switch (3J); a third lead contact of the third switch member (3j) connected to the coil of the sixth relay (30), one lead contact of the fourth switch member (3) connected to the second lead contact of the switch member (3), the coil of the fourth pulse counter (29) connected to the break contact of the sixth relay (30), e.g. the make contact is connected to the make contact of the third relay (17).