CS227741B1 - Connexion for electromechanical cycling - Google Patents

Description

The present invention relates to an electromechanical cycling circuit with operation equipment using a preselected electromechanical pulse counter.

The known connection of the repetitive time pulse source, their length and the length of the gaps between them is controlled with the possibility of counting time pulses and automatic shutdown of the device, consisting of two timing relays and electromechanical pulse counters mainly disadvantages in that reproducibility of adjusted times is difficult , considerable fluctuations in time, heavy weight and volume, frequent failure rates and demanding maintenance.

These shortcomings of time cycling are eliminated by the proposed circuit.

SUMMARY OF THE INVENTION The switching contact of the fourth relay is connected to the switching contact of the third relay, the switching contact of the fourth relay to the counter of the second pulse counter, the NC contact of the fourth relay to the counter of the first pulse counter. pulse counter, switching contact of the first pulse counter to the coil of the fourth relay, lubrication solenoid of the first pulse counter to the switching contact of the second pulse counter, changeover contact of the second pulse counter to the NC contact of the third pulse counter, pulses to the counting solenoid of the third pulse counter, the counting solenoid of the third pulse counter to the switching contact of the fifth relay and contact of the third pulse counter to the total clock.

The advantage of the proposed wiring lies in the simple, precise setting of reproducible rearranged time cycles.

The attached drawing shows a schematic connection to an electromechanical encyclical with operation equipment.

The connection consists of a mains supply A connected to the switches, a switch B connected to the third pulse counters and the first relay C, connected to the second and third relays, the first diode D connected to the power member; a first resistor JE connected to the first diode; a second resistor F connected to the first diode; a first potentiometer G connected to the first resistor; a second potentiometer H connected to the second resistor; a third resistor CH connected to the first relay; a fourth resistor I connected to the first relay; a first capacitor J connected to the first relay; a second capacitor K connected to the first capacitor; a first plate L connected to a first potentiometer and a capacitor and a third resistor; a second attack M connected to a second potentiometer and a capacitor and a fourth resistor; a second relay N connected to the first diac and the first capacitor; a third relay 0 connected to the second remote and the second relay; a power member 6 connected to a temperature controller; a temperature controller 0 connected to the switches; a fourth relay R connected to a temperature controller and a first pulse counter and a third relay; a first pulse counter g coupled to a second pulse counter; a second pulse counter I connected to the second diode i of the third pulse counter; a third pulse counter U connected to the power member i of the third and fifth relays; a second diode V connected to a fifth resistor; a fifth resistor ‘W connected to a third capacitor and a diac; a third capacitor X connected to the fifth relay; a third diac Y, connected to the fifth relay; of the fifth relay Z, connected to the second relay i to the third pulse counters and the total clock Ž, connected to the third pulse counters and to the fifth relay.

We use the wiring according to the invention such that to the free sets of relay contacts R by connecting the thermocouple and the runner of one and the other setpoint potentiometer, the resistance branch of the measuring branch and the output of one and the other setpoint potentiometer and a slider of both the cycle regulator power setting potentiometer. On the pulse counters S, T, a default value of the desired time pulses is set. By switching on the splitter B, the first supply A of the network A is brought through the make and break contact of the third pulse counter g to the summation clock Z, the power member P, the controller 2 having the second outlet of the network A directly connected and actuated. Clearing hours Z count down the running time of the device. The contacts of the fourth relay R connect one terminal of the thermocouple to the runner of one setpoint potentiometer and the terminal of the measuring string branch to the outlet of one setpoint potentiometer of the setpoint potentiometer as well as the other.

Said temperature controller 2 operates according to the control deviation through the power member P the power to the appliance. At the same time, the line voltage is applied to the time circuits, where the first capacitor 11 is charged via the first diode D, the first resistor a and the first potentiometer G. After reaching the switching voltage of the first deacon L, part of the hub of the first capacitor J is discharged into the slider of the second relay N, which is energized for a moment and energizes the first relay 6 to close by closing the switching contact. In the first folded contact, the relay 6 is held in further operation, in the second folded contact, a third discharge resistor CH is connected to the first capacitor J and the fourth discharge resistor J is disconnected from the second capacitor K, and first diode £, second resistor F and second potentiometer H, the second capacitor K is charged. Upon reaching the switching voltage of the second diac M, the part of the charge of the second capacitor K is transferred to the coil of the third relay 0, which momentarily excites and breaks the circuit of the first relay. relay 0 is applied a voltage pulse via the first break contact of the fourth relay g to the first pulse counter S, which counts one pulse.

In the first folded contact of the first relay C, the voltage supply to this relay is interrupted and the fourth discharge resistor 2 is connected to the second capacitor K, in the second folded contact of the relay 8, the third discharge resistor CH is disconnected from the first capacitor J and periodically described the process up to the number of pulses transmitted by the third relay 0 reaches the default value of the pulse counter § by switching its changeover contact, which energizes the coil of the fourth relay R, which draws and switches its relay contacts and one terminal of the thermocouple to the runner of the second setpoint potentiometer as well as the resistance outlet of the mSstik branch to the outlet of the second setpoint of the setpoint potentiometer as well as the second breaker contact of the temperature controller and the runner of the second setpoint potentiometer on the performance of the minimum cycle value.

The interrupt circuits measure the times described by the second pulse counter X until the number of pulses transmitted by the third relay 0 reaches the default value of the pulse counter X, when the changeover contact is switched to the second contact of network A to the lubrication solenoid of the first pulse counter. S, what is its numeric reset to zero? In the translated contact of the first pulse counter S, the coil circuit of the fourth relay R is broken, which drops off and switches the counting electromagnet of one pulse counter to the third relay 0 and ensures the connection of the described elements over the maximum cycle value. At the same time, from the switched-on contact of the second pulse counter T, the second supply of network A is connected to another time circuit, where the fifth resistor W is charged via the second diode V, the third capacitor X. After reaching the switching voltage of the third deactivator Y, part of the charge of the third capacitor X into the coil of the fifth relay Z, which momentarily excites and closes its switching contact to feed the second ρΐ'ίνο'ά network to the second electromagnetic pulse counter X to the electromagnet of the third pulse counter U, thereby resetting the numeric state and the second contact pulses X and one pulse corresponding to the course of one complete cycle is recorded in the third pulse counter U.

Further coherent cycles proceed as described until the number of pulses transmitted by the fifth relay 8 reaches the default value of the third pulse counter U, when the second contact of the network A to the device which is thus deactivated is interrupted by translating its changeover contact. The device is brought to this state by switching off switch B.

Further operation of the device can be resumed by resetting the numeric state of the third pulse counter 6, its reset button, which also translates its changeover contact into the operating state, and by switching on the switch B the device is in further operation.

The wiring according to the invention can advantageously be used for cyclic thermal stress.

Claims (2)

1. Electromechanical cycling circuit with operation equipment characterized in that the changeover contact of the fourth relay (R) is connected to the switching contact of the third relay (0), the switching contact of the fourth relay (R) to the counter electromagnets of the second pulse counter (T). contact of the fourth relay (R) to the counting electromagnets of the first pulse computer (S), the switching contact of the first pulse computer (S) to the switching contact of the second pulse computer (T), the switching contact of the first pulse computer (S) to the coil of the fourth relay (R) the first pulse computer (S) lubricating solenoid to the second pulse computer (T) make contact, the second pulse computer (T) make contact to the third pulse computer (U) make contact, the second pulse computer (T) make contact to the second diode (V) , a second electromagnetic counter (T) lubricating solenoid to a counter of the third electromagnets a pulse counter (U) and a counting solenoid (U) of the third pulse computer (U) to the switching contact of the fifth relay (Z). 2. Electromechanical cycling circuit with operation equipment according to clause 1, characterized in that the break contact of the third pulse counter (U) is connected to the summation clock (2).