CS269235B1 - Connection of controller's input bridge - Google Patents

Abstract

The connection is intended to ensure the function of trailing control of two temperatures, when the setpoint of one temperature depends on the instantaneous temperature value of the other. The dependence of both temperatures can be represented by a working curve, e.g. a straight line, for which the slope can be set, or a parallel shift without changing the slope of the working line. The bridge circuit allows the connection of a resistive feedback transmitter to improve the dynamic properties of the controller. The connection also includes a night attenuation circuit, which, depending on the state of the timer, changes the parallel shift of the working curve and thus, e.g. at night, reduces the water temperature in the heating system.

Description

The invention relates to the connection of the input bridge of the regulator, consisting of the terminals of the voltage source, a resistance bridge with two temperature sensors and a feedback circuit, an amplifier and a night-time attenuation circuit.

For the regulation of the thermal output of transfer stations, the regulation of the water temperature, or the average water temperature in the heating system, depending on the outdoor temperature is often used. For these purposes, trailing control regulators are manufactured, in which the slope and parallel shift of the operating curve of the regulator can be adjusted using the control elements, i.e. the dependence between the water temperature in the heating system and the outdoor air temperature. To improve the dynamic properties of the regulators, these are equipped with internal feedback, for example, fixed feedback by a resistance transmitter from the position of the servomotor. When implementing this feedback, a special resistance bridge with an amplifier is usually used, amplifying the voltage of the bridge diagonal, which depends on the instantaneous position of the actuator of the control circuit, i.e. on the deflection of the current resistance transmitter. The output voltage of the feedback amplifier is usually introduced to the input of the summing amplifier, where voltage signals from the control deviation amplifier and the night-time attenuation amplifier are also introduced. The control deviation is given by the difference between the actual instantaneous water temperature and the temperature corresponding to the instantaneous outside air temperature, at the selected operating curve, i.e. the dependence of the water temperature on the air temperature. The night-time setback amplifier is a part of the night-time setback circuit ensuring that the timer contact switches at certain hours, usually at night. The auxiliary circuit then generates a voltage signal, which, after being amplified and introduced to the input of the summing amplifier, causes the controller operating curve to shift and the water temperature in the heating system to decrease.

This ensures that the thermal output of the transfer station is reduced during night hours and thermal energy is saved.

The above controller circuit thus contains the circuits of a resistance bridge of water temperature and outdoor temperature sensors with an amplifier, a feedback bridge with a resistance transmitter and an amplifier, a night-time attenuation circuit with a timer and an amplifier, and a summing amplifier for combining and comparing individual voltage signals.

This solution significantly worsens the reliability of the device, its resistance to temperature changes and, due to the sudden change in the operating curve caused by night-time reduction, often causes unwanted pressure surges in the heating network when the timers of a large number of controllers are set to the same hour for the start and end of night-time reduction.

These shortcomings are largely eliminated by the connection of the input bridge of the controller according to the invention, the essence of which lies in the fact that the voltage center terminal is connected, firstly, via a capacitor to the control electrode of the transistor, secondly, to the normally closed contact of the timer, and secondly, via a resistive water temperature sensor to the first terminal of the resistive outdoor temperature sensor. The second terminal of the resistive outdoor temperature sensor is connected, via the first bridge resistor, to the first terminal of the correction variable resistor, the second terminal of which is connected to the first terminal of the resistive transmitter. The runner of the resistance transmitter is connected to the negative supply terminal of the bridge and the second terminal of the resistance transmitter is connected via a third bridge resistor to the first terminal of the feedback sensitivity variable resistor, the second terminal of which is connected to the first terminal of the correction variable resistor, while the first terminal of the feedback sensitivity variable resistor is connected via a second bridge resistor to the first terminal of the parallel combination of the curve shift sensitivity resistor and the curve shift potentiometer, the second terminal of which is connected via a second range resistor to the first terminal of the curve selection variable resistor, the second terminal of which is connected via the curve selection range resistor to the first terminal of the outdoor temperature resistance sensor. The first terminal of the variable resistor is connected via the first range resistor to the voltage center terminal, which is connected via the night attenuation potentiometer to the anode of the diode. The cathode of the diode is connected to the emitter of the transistor and, through a variable emitter resistor, to the negative supply terminal, which is connected to the negative supply input of the amplifier and to the working contact of the timer. The common contact of the timer is connected to the control electrode of the transistor through the base resistor, whose collector is connected to the positive supply terminal and to the positive supply input of the amplifier, whose non-inverting input is connected to the slider of the curve shift potentiometer through the third input resistor. The inverting input of the amplifier is connected to the second output of the resistance outdoor temperature sensor through the second input resistor.

firstly through the first input resistor with the slider of the night attenuation potentiometer and secondly through the feedback resistor with the amplifier output.

The advantage of the connection of the input bridge of the controller according to the invention is that it combines in the resistor bridge circuit, in addition to the functions usual for the input circuits of trailing control controllers, the function of fixed feedback by the resistor transmitter from the position of the servomotor. The slope and parallel shift of the operating curve of the controller, i.e. the dependence between the water temperature in the heating system and the outside air temperature, can be changed in a simple way and within wide limits. The proportionality band of the fixed coupling is arbitrarily variable and the bridge power supply via the slider of the resistor transmitter significantly suppresses the influence of the transition resistance between the slider and the resistance path. The advantages of the connection include simple adjustment, high sensitivity of night attenuation and smooth start-up of the effect of night attenuation. Another advantage is the use of a single amplifier for combining and amplifying the signals of the control deviation, feedback and night attenuation. An example of the connection of the input bridge of the controller according to the invention is schematically shown in the attached drawing.

Terminal 1 of the voltage center is connected via a capacitor to the control electrode 23 of the transistor 22, via a normally closed contact 27 of the timer 26 and via a water temperature resistance sensor 6 to the first terminal of the outdoor temperature resistance sensor 7. The second terminal of the outdoor temperature resistance sensor 7 is connected via the first bridge resistor 2* to the first terminal of the correction variable resistor 17, the second terminal of which is connected to the first terminal of the resistance transmitter 19. The runner of the resistance transmitter 29 is connected to the negative supply terminal 2 of the bridge and the second terminal of the resistance transmitter 19 is connected via the third bridge resistor 18 to the first terminal of the feedback sensitivity variable resistor 16, the second terminal of which is connected to the first terminal of the correction variable resistor 17, while the first terminal of the feedback sensitivity variable resistor 16 is connected via the second bridge resistor 22 to the first terminal of the parallel combination of the curve shift sensitivity resistor 12 and the curve shift potentiometer 22, the second terminal of which is connected via the second range resistor 9 to the first terminal of the curve selection variable resistor 11, the second terminal of which is connected via the range resistor ^0 of the curve selection to the first output of the resistance sensor 7 of the outdoor temperature. The first output of the variable resistor 21 of the curve selection is connected via the first range resistor 8 to the terminal 2 of the voltage center, which is connected via the potentiometer 20 of the night attenuation to the anode of the diode 21. The cathode of the diode 22 is connected on the one hand to the emitter of the transistor 22 and on the other hand via the variable emitter resistor 36 to the negative supply terminal 4, which is connected on the one hand to the negative supply input of the dimmer 5 and on the other hand to the working contact 28 of the timer 26. The common contact 37 of the timer 26 is connected via the base resistor 25 to the control electrode 23 of the transistor 22, the collector of which is connected on the one hand to the positive supply terminal 3 and on the other hand to the positive supply input of the amplifier 5, the non-inverting input 34 of which is connected via the third input resistor 32 to the slider of the potentiometer 23 of the curve shift. The inverting input 33 of the amplifier 5 is connected, on the one hand, via the second input resistor 30, to the second terminal of the resistance sensor 2 of the outdoor temperature, on the other hand, via the first input resistor 2£ to the slider of the potentiometer 20 of the night attenuation, and on the other hand, via the feedback resistor 32 to the output 35 of the amplifier 5.

The circuit works as follows: The bridge supply voltage is given by the voltage difference between terminal 2 of the voltage center and the negative supply terminal 2 of the bridge. The first branch of the bridge, consisting of a water temperature resistance sensor 6, an outdoor temperature resistance sensor 7, a first bridge resistor 14, a correction variable resistor 17 of a part of the resistance path of the resistance transmitter 19, flows approximately the same current as the second branch of the bridge, formed by the first range resistor 8, the second range resistor 9, a parallel combination of the curve shift sensitivity resistor 12 and the curve shift potentiometer 13, the second bridge resistor 15, the third bridge resistor 18 and a part of the resistance path of the resistance transmitter 19. The sensitivity of the dependence of the bridge diagonal voltage on the impedance of the water temperature resistance sensor 6 is set using the curve selection range resistor 10 and the curve selection variable resistor 11. In the case of a minimum value of the curve selection variable resistor 11, the sensitivity is minimal and vice versa. By changing the variable resistor 11 of the curve selection, it is therefore possible to adjust the slope of the controller's operating curve, i.e. the dependence between the water temperature and the outdoor temperature.

CS 269235 B1 3 air. The first range resistor 8 and the second range resistor 9 are used to set the beginning and end of the operating curve of the regulator. The parallel shift of the operating curve depends on the position of the slider of the curve shift potentiometer 13. The sensitivity of the dependence of the position of the slider of the curve shift potentiometer 13 on the parallel shift depends on the value of the curve shift sensitivity resistor 12.

The input bridge also includes an auxiliary feedback bridge, consisting of a correction variable resistor 17, a third bridge resistor 18, a resistive transmitter 19 and a variable resistor 16 for feedback sensitivity. The voltage of the input bridge diagonal, fed via the second input resistor 30 and the third input resistor 31 to the inverting input 33 of the amplifier 5 and the non-inverting input 34 of the amplifier 5, depends, in addition to the setting of the operating curve and the value of the water temperature and the outside temperature, also on the effect of the feedback.

The maximum feedback sensitivity is when the variable resistor 16 of the feedback sensitivity is set to the maximum value. The differential voltage between the inverting input 33 of the amplifier 5 and the non-inverting input 34 of the amplifier 5 also affects the auxiliary voltage signal of the night attenuation, controlled by the timer 26. After the timer 26 is switched on, i.e. after the conductive connection of the common contact 37 of the timer 26 with the working contact 28 of the timer 26, the capacitor 24 begins to be charged with the voltage of the negative supply terminal 4 through the base resistor 25. This begins to reduce the voltage of the driver electrode 23 of the transistor 22 and the transistor 22 begins to reduce its conductivity. At this time, the voltage of the emitter of transistor 22 begins to decrease, because the voltage divider between the positive supply terminal ^ and the negative supply terminal £, formed by transistor 22 and variable emitter resistor 36, is adjusted by variable emitter resistor 36 for the idle state of timer 26 so that the voltage at the emitter of transistor 22 is exactly the same as the voltage at terminal 1 of the voltage center. The decrease in voltage of the emitter of transistor 22 is transferred via diode 21 to the night attenuation potentiometer 20. From the slider of the night attenuation potentiometer 20, this negative voltage signal is further conducted via the first input resistor 29 to the inverting input 33 of amplifier J5, where it acts in such a way that a parallel shift of the operating curve of the regulator occurs and the water temperature corresponding to the outdoor temperature decreases.

The feedback resistor 32 influences the gain of the amplifier _5, whose output 35 is also the output of the controller input bridge circuit.

The invention will be used in measurement and control technology in the construction of measurement and control devices.

Claims (1)

SUBJECT OF THE INVENTION Connection of the input bridge of the regulator, characterized in that the terminal /1/ of the voltage center is connected, on the one hand, via a capacitor /24/ to the control electrode /23/ of the transistor /22/, on the other hand, to the normally open contact /27/ of the timer /26/ and on the other hand, via a water temperature resistance sensor /6/ to the first output of the outdoor temperature resistance sensor /7/, the second output of which is connected via a first bridge resistor /14/ to the first output of the correction variable resistor /17/, the second output of which is connected to the first output of the resistance transmitter /19/, the runner of which is connected to the negative supply terminal /2/ of the bridge and the second output of which is connected via a third bridge resistor /18/ to the first output of the feedback sensitivity variable resistor /16/, the second output of which is connected to the first output of the correction variable resistor /17/, while the first output of the feedback sensitivity variable resistor /16/ is connected via the second bridge resistor /15/ is connected to the first terminal of the parallel combination of the curve shift sensitivity resistor /12/ and the curve shift potentiometer /13/, whose second terminal is connected via the second range resistor /9/ to the first terminal of the variable resistor /11/ of the curve selection, whose second terminal is connected via the range resistor /10/ of the curve selection to the first terminal of the resistance sensor /7/ of the outdoor temperature, while the first terminal of the variable resistor /11/ is connected via the first range resistor /8/ to the terminal /1/ of the voltage center, which is connected via the night attenuation potentiometer /20/ to the anode of the diode /21/, whose cathode is connected both to the emitter of the transistor /22/ and via the variable emitter resistor /36/ to the negative supply terminal /4/, which is connected both to the negative supply input of the amplifier /5/ and to the working contact /28/ of the timer /26/, whose common contact /37/ is connected via a base resistor /25/ to the control electrode /23/ of the transistor /22/, whose collector is connected both to the positive supply terminal /3/ and to the positive supply input of the amplifier /5/, whose non-inverting input /34/ is connected via a third input resistor /31/ to the slider of the curve shift potentiometer /13/ and whose inverting input /33/ is connected via a second input resistor /30/ to the second terminal of the outdoor temperature resistance sensor /7/, via a first input resistor /29/ to the slider of the night-time attenuation potentiometer /20/ and via a feedback resistor /32/ to the output /35/ of the amplifier /5/.