CS227933B1 - Connection to temperature control option - Google Patents

Abstract

The invention relates to a circuit for selecting temperature control with the possibility of time switching using electromechanical pulse counters. The essence is that one output contact of the switch is connected to the first to fourth supply contacts of the first part of the switch, the first output contact of the first part of the switch to the third and fourth supply contacts of the second part of the switch and to the second supply contact of the third part of the switch and to the temperature controller, the second output contact of the first part of the switch to the switching contact of the third pulse counter, the third and fourth output contacts of the first part of the switch to the switching contact of one pulse counter, the second input contact of the second part of the switch to the coil of the fourth relay, the second and third output contacts of the second part of the switch to the switching contact of one pulse counter, the fourth output contact of the second part of the switch is connected to the third and fourth output contacts of the fourth part of the switch and connected to the break contact of one pulse counter, the second output contact of the third part of the switch is connected to the second output contact of the fourth part of the switch part of the switch i is connected to the opening contact of the third pulse computer bv, the second to fourth supply contacts of the fourth part of the switch are connected to one diode and one point of the contact clock to the temperature controller. The connection can also be used to select the regulation of other automation devices.

Description

The invention relates to a wiring for the choice of temperature control with the possibility of time switching using electromechanical pulse counters. '

The known circuitry for cyclic temperature control using electromechanical pulse counters is chosen as a single purpose, disadvantageous for other types of temperature control than without the possibility of a time switch.

The above-mentioned disadvantages of cyclic temperature control and electromechanical pulse counters are eliminated and the extension of its use is ensured by the proposed wiring.

SUMMARY OF THE INVENTION One terminal contact of the switch is connected to the first to fourth terminal contacts of the first switch member, the first terminal contact of the first switch member to the third and fourth terminal contacts of the second switch member and the second terminal contact of the third switch member and the temperature controller; first contact of the first part of the switch to the switching contact of the third pulse counter, third and fourth terminal of the first part of the switch to the switching contact of one pulse counter, the second contact contact of the second part of the switch to the target of the fourth relay pulse counter, the fourth terminal contact of the second switch member is coupled to the third and fourth terminal contacts of the fourth switch member i connected to the break contact of one the second terminal contact of the third switch member is coupled to the second terminal contact of the fourth switch member i connected to the break contact of the third pulse counter, the second to fourth terminal contacts of the fourth switch member are connected to one diode and one sum clock point to the temperature controller.

The advantage of the connection lies in the fully automated operation of both cycling and automatic temperature control with the possibility of time switching, saving electricity.

The attached drawing shows a schematic circuit for cyclic temperature control with electromechanical pulse counters with switching to automatic with time switching.

The circuit according to the invention consists of a lead wire connected to the switches. switch 2 connected to both temperature controller and switches and one relay? switch .3 connected to one and third pulse counters and the fourth relay? one relay 4 connected to the second and third relay and one and the other capacitor? one diode 5 connected to switches? one resistor 6 connected to one diode, the other resistor 7 connected to one diode? one potentiometer 8 connected to one resistor? the second potentiometer connected to the second resistor? a third resistor 10 connected to one capacitor and one relay? the fourth resistor 11 connected to the second capacitor and one relay, one capacitor 12 connected to one potenoi? a second capacitor 13 connected to a second potenoiometer? one diaper 14 connected to one potenoiometer? a second diacana 15 connected to a second potenoiometer? a second relay 16 connected to one diac and a capacitor and a direct relay, a third relay 17 connected to the second diac and a capacitor, and a fourth relay? temperature controller 18 connected to the switches? a power member 19 connected to a temperature controller? a fourth relay 20 connected to one or both pulse and switch counters? one pulse computer 21 connected to the other pulse and switch computers? a second pulse counter 22 connected to a third pulse counter and a second diode? a third pulse computer 23 connected to the switches i to the third and fifth relays? the second diode 24 connected to the fifth resistor? the fifth resistor 25 connected to the third diac? the third capacitor 26 connected to the fifth resistor and the fifth relay? a third deacon 27 connected to the fifth relay? a fifth relay 28 connected to the total clock and the third pulse counters and the total clock 29 connected to the temperature controller.

We use the wiring according to the invention by connecting the thermocouple and the slider of the setpoint setpoint, the cycle, the resistance of the measuring point branch, the output of both the setpoint setpoint potentiometer, the second temperature regulator break contact and the slider one and the other of the cycle control power setting potentiometer.

In the first position of the switch 2, automatic temperature control takes place and by switching the switch, one inlet of the slide 2 is directly connected to the individual sources of the device. The second mains supply 1 is connected via the first closed contact of the first part of the switch 2 ^to the temperature regulator 18 and the power element 19 ' ^and to the total clock 29 These actuations are activated and the individual power inputs are automatically adjusted by the temperature regulator 18 according to the control deviation through the power element 19 and the total operating time is calculated by the summation clock 29. The device is brought to the idle position by switching off switch 2.

In the second position of the switch 3, periodic cyclic regulation takes place. A default pulse value is set on the pulse counters 21, 22, 23. By closing the switch 2, one mains supply 2 is directly connected to the device, the other through the second closed contact of the first part of the switch 2 to the changeover contact of the third pulse counter 23 and its break contact and the second closed contact of the third part of the switch 2 to the temperature controller 18 and the power element 19 the total hours 29. »which are activated, the total hours 29 count the total operating time. The contacts of the fourth relay 20 connect one terminal of the thermocouple to the runner of one potentiometer setpoint and the resistance of the measuring bridge branch to the outlet of one potentiometer setpoint potentiometer as well as the other breaker contact of the temperature controller to the runner of one potentiometer.

The temperature controller 18 actuated controls the power input to the appliance according to the control deviation via the power member 19. At the same time, a second mains lead is supplied through the second closed contact of the fourth part of the switch 2 ^{to the} time circuits, where one capacitor 12 is charged through one diode 5, one resistor 2 and one potentiometer 2. After reaching the switching voltage of one diac 14 The second relay 16 is energized into the coil and is energized for a moment and energizes one relay 6 which closes by closing the switching contact.

In the first relayed contact of this relay 6, the relay is held in operation and in the second relayed contact of relay 4 a third discharge resistor 10 is connected to one capacitor 12 and the fourth discharge resistor 11 is disconnected from the second capacitor 13 and through one diode 5, second resistor 7. and the second potentiometer 2 charges the second capacitor 22. · ^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 which excites for a moment and breaks the circuit of one relay 4. by connecting the make contact of this third relay 17, a pulse is applied via the break contact of the fourth relay 20 to one pulse counter 21 which counts it.

In the first relayed contact of one relay 4, the voltage supply for this relay is interrupted, and in the second relayed contact, the fourth discharge resistor 11 is connected to the second capacitor 22. and the third discharge resistor 10 is disconnected from the first capacitor 12, until the number of pulses transmitted by the third relay 17 reaches the default value of one pulse counter 21, when its changeover contact, switching the second ground connection 2 from the break contact of the third pulse counter 23 through the second closed contact of the second switch 3 to the coil of the fourth relay 22 and in its folded contacts the switching contact of the third relay 17 connects to the second pulse counters 22 and one thermocouple pole to the runner of the second setpoint potentiometer as well as the terminal of the measuring bridge branch to the second setpoint potentiometer the setpoint value of the cycle as well as the second break contact of the temperature regulator to the runner of the second potentiometer setting the minimum cycle value. The timing circuits measure the times described in the manner described by the second pulse counter 22 until the number of pulses transmitted by the relay 22 reaches the default value of the second pulse counter 22, by switching its changeover contact. the pulse switch 23 to the lubricating electromagnet of one pulse counter 21, which resets its numeric state and translates its own changeover 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 maximum cycle value. At the same time, from the switch contact of the second pulse counter 22, the second lead of the slide 2 is also fed to another time circuit where the capacitor 26 is charged via the second diode 24, the fifth resistor 25.

After reaching the switching voltage of the third deacon 27, part of the charge of the third capacitor 26 is discharged into the coil of the fifth relay 28, which is excited for a moment and energizes the second supply of network 2 to the lubrication solenoid 22 of the second pulse counter 22. changeover contact. At the same time, the voltage pulse of the fifth relay 28 is recorded by a third pulse counter 22 as a single cycle.

The subsequent complete cycles periodically run in the same manner when the number of pulses sent by the fifth relay 28 reaches the default value of the third pulse computer 23, when the entire device is automatically disabled from the next operation by translating its own changeover contact. It is brought to a standstill by switching off the switch 2 and resetting the numerical state by the button of the third pulse counter 23.

In the third position of the switch 2 there is an automatic temperature control with the possibility of switching on the device in time. A default pulse counter corresponding to the switch-on time is set on one .21 pulse counter. By switching the switch 2, one mains supply is connected directly to the alignment via the third closed contact of the first part of the switch 3, the contacts of one pulse counter 21, the third closed contact of the fourth part of the switch 2 to one diode 2. pulses 21, which in the open NC contact disconnects the second mains supply for the timing circuits and in the closed contact switches the second mains supply via the third closed contact of the second part of the switch 2 ^to the temperature controller 18 and the power member 19; The charging clock 29 counts down the operating time and the individual power inputs are automatically adjusted by the temperature controller 18 according to the control deviation through the power member 19. The device is brought to a standstill by switching off the switch 2.

In the fourth position of the switch 2, the automatic temperature control and the time switch-off of the device take place. On one pulse counter 21, a default value of time pulses corresponding to the switch-off time is set. By switching on the switch 2, one mains supply is connected directly to the device and the other through the fourth closed contact of the first part of the switch 2 ^{and the} contacts of one pulse counter 21 1 the fourth closed contact of the second part of the switch 2 to the temperature controller 25. are activated. The clock counts down the operating time and the individual power inputs are automatically adjusted by the temperature controller 18 according to the control deviation through the power member 19.

At the same time, the second mains supply from the second NC contact of one pulse counter 21 is connected to the diode 2 from the fourth normally closed contact of the fourth part of the switch 2 ^{and the} time sequence described above is repeated until the changeover contact of one impulse counter 21 is switched. 18, the power member 19, the summation clock 29 as well as for the timing circuits, thereby disabling the device from further operation and bringing it to a standstill by switching off the switch 2.

The circuit according to the invention can also be used to select the control of other automation devices.

Claims (2)

OBJECT OF THE INVENTION 1. The temperature control selection circuit is characterized in that one switch contact of the switch (2) is connected to the first to fourth lead contacts of the first switch part (3), the first lead contact of the first switch part (3) to the third and the fourth lead contact of the second the second terminal contact of the first part of the switch (3) to the changeover contact of the third pulse counter (23), the third and fourth terminal contacts of the first part of the switch (3) and the temperature regulator (18); 3) for a changeover contact of one pulse counter, a second lead contact of a second switch section (3) to a fourth relay coil (20), a second and a third terminal contact of a second switch section (3) to a switch contact of one pulse counter (21), a fourth lead the second part of the switch (3) is connected to the third and fourth outlet wheels at the time of the fourth part of the switch (3) connected to the break contact of one pulse counter (21), the second terminal contact of the third part of the switch (3) is connected to the second terminal contact of the fourth switch part (3/1) and the second to fourth inlet contacts of the fourth part of the switch (3) are connected to one diode (5). 2. Wiring to select the temperature control according to item 1, characterized in that one point of the total clock (29) is connected to the temperature controller (18).