SU1545036A1 - System for automatic regulation of usersъ inlet of central heating network - Google Patents

Abstract

The invention relates to the heat supply of residential, public and industrial complexes having a central heat input from a CHP plant. The aim of the invention is to improve the quality of regulation. In the summer mode, the DHW temperature is controlled by the regulator 1 by acting through the switch 13 on the actuator 3, which changes the position of the valve 4, with a decrease in the DHW temperature, the valve 4 is opened, and closed with an increase. In winter mode, the heat carrier of CHP through the pressure regulating valve 4 is supplied to the inlet of the three-way valve 11, from the output of which is fed to the input of the second stage B of the DHW preheater and bypassing it and then through the valve 19 to the heating system, from where the spent coolant through the valve 21 and the first stage A of the DHW heater returns back to the CHP plant. The charge cold water through the check valve 22 and the first stage 4, mixing with the circulation water from the DHW line by means of the circulation pump 5 through the second stage B of the preheater, is fed into the DHW subscription system. In this mode, valves 19 and 21 are open, valve 20 is closed, switch 13 is in the Winter position, the valve actuator 4 is connected to the output of the differential pressure controller 2 and the actuator 12 of the three-way valve 11 is connected to the output of the DHW temperature regulator 1. 2 Il.

Description

1

the regulator 1 by acting through the switch 13 on the actuator 3, which changes the position of the valve 4, opens the valve 4 when the DHW temperature decreases, and closes with increasing. In winter mode, the heat carrier of CHP through the pressure regulating valve 4 is supplied to the inlet of the three-way valve 11, from the output of which is fed to the inlet of the second stage B of the DHW preheater and bypassing it and then through the valve 19 to the heating system, from where the spent coolant through the valve 21 and the first step A hot water heater

Returns back to CHP. The sub-cold water through the check valve 22 and the first stage 4, mixing with the circulation water from the DHW line by means of the circulation pump 5 through the second stage B preheater, is fed into the subscriber's DHW system. In this mode, valves 19 and 21e are open, valve 20 is closed, switch 13 is in the Winter position, connecting the actuator of the valve 4 to the output of the differential pressure controller 2 and the actuator 12 of the three-way valve 11c with the output of the controller 1 of the DHW temperature. 2 Il.

The invention relates to the heat supply of residential, public and industrial complexes having a central heat input from a CHP plant.

The purpose of the invention is to improve the quality of regulation.

Figure 1 shows a functional adjustment circuit; FIG. 2 is a circuit diagram of an analog thermocouple of the temperature of the direct heat carrier of the heating system.

The system of automatic control of subscriber input of the heating system with the sequential activation of two stages A and B of the combustible water heater (DHW) contains a controller 1 for the temperature of the hot water supply regulator 2 pressure differential in the pipelines of the direct and reverse heat carrier connected to the actuator 3 of the control valve 4 differential the pressure installed in the pipeline of the direct heat carrier, the circulation pump 5 and the subming pump 6 with the drive 7 connected to the control unit 8 and regulate Submerge valve 9 with actuator 10, three-way valve 11 with actuator 12, switch 13 for winter and summer control modes, pulse interrupter 14 and temperature difference controller 15 with an analogue thermocouple 16 of the temperature of the direct heat carrier for the subscriber's return heat carrier on heating

graphics and sensor 17 of the return heat medium temperature, the control valve 4 of the differential pressure is installed to the second stage of the heater and connected to the outlet of the three-way valve 11, the outputs of which are connected respectively to the inlet and outlet of the second stage of the hot water heater.

Subsize control valve 9 is installed parallel to the submix pump 6, the actuator 10 of the submix valve 9 is connected to the temperature differential controller 15 via a pulse interrupter 14, the actuator 7 of the submix pump 6 is connected to the control unit 8 via the limit switch 18 fully open the submix valve 9, and The actuator 3 of the differential pressure regulating valve 4 is connected to the differential pressure regulator 2 via switch 13 of the winter and summer control modes set to the winter mode and connected via switch 13 of winter and summer control modes, set for summer mode, to controller 1 of the hot water supply temperature; Actuator 12 of the three-way valve 11 is connected to controller 1 of hot water supply through switch 13 of winter and summer modes set for winter mode. In addition, the system contains valves 19-21 and check valves 22 and 23.

Analogue Direct Transmitter The heating network in the temperature of the return heat carrier, the subscriber according to the heating schedule contains two sequentially connected thermoprocessors 24 and 25 with a resistor 26 connected in parallel.

The automatic control system works as follows.

Summer mode (inter-heating season). The valves 19 and 21 are closed, the valve 20 is open, the switch 13 is in the Leto position, connecting the actuator 3 of the control valve 4 to the output of the DHW temperature controller 1. At the same time, both V stages B and A of the DHW heaters turn on the coolant sequentially. The three-way valve 11 is fully open in the direction of the second stage B of the DHW heater and is closed bypassing it. The differential pressure controller 2, the pump 6 with the drive 7 and the control unit 8, the mixing valve 9 with the actuator 10 and the temperature difference controller 15 with the chopper 14 do not participate in the control process.

The DHW temperature is controlled by the regulator 1 by acting through the switch 13 on the actuator 3, which changes the position of the valve 4: when the DHW temperature drops, the valve 4 opens, closes when raised.

Winter mode. The valves 19 and 21 are open, the valve 20 is closed, the switch 13 is in the Winter position, connecting the actuator of the valve 4 with the output of the pressure differential controller 2 and the actuator 12 of the three-way valve 11 with the output of the controller 1 of the DHW temperature. In this case, both stages B and A of the DHW preheater are switched over the coolant in series with the heating system.

The heat carrier of CHP through the pressure regulating valve 4 is supplied to the inlet of the three-way valve 11, from the output of which is fed to the input of the second stage B of the DHW preheater and bypassing it and then through the valve 19 to the heating system, from where the spent coolant through the valve 21 and the first stage A under the

50366

The warmer G.S. returns back to the CHP.

The charge cold water through the check valve 22 and the first stage A, mixing with the circulation water from the DHW line by means of the circulation pump 5 through the second stage B of the preheater, is fed into the subscriber DHW system.

The regulator 2 of the differential pressure of the subscriber’s heating system selects the position of the control valve 4 through the switch 13 through the heating mechanism throughout the heating period so that the differential pressure of the heating system is constant: when the differential drops, the valve 4 opens: with increasing the pressure is closed.

ten

15

20

0

The controller 15 by means of an analogue thermal converter 16 measures the temperature of the direct heat carrier.

5 CHP, converts it to the temperature of the subscriber's return heat carrier in accordance with the heating schedule, compares this graphic temperature using sensor 17 with the actual temperature of the return heat carrier of the subscriber returned to the CHP plant, and sends a control signal through pulse interrupter 14 to actuator 10, which moves the control valve 9 mixes. When the subscriber returns the heat carrier to the CHP with the temperature too high with respect to the heating schedule, the controller 15 pulses through the interrupter 14 and closes valve 9 with the help of mechanism 10. When the valve 9 moves, from the full open position to close it closes its end

5, the switch 18 and the control unit 8, by means of the actuator 7, turn on the subming pump 6, which begins to partially mix the spent coolant through the check valve 23 into the straight line of the heating system, and partly through the still open valve 9 again into the return line of the heating system. The degree of mixing of the return heat medium to the straight line of the heating system is determined by the position. control valve 9: the more it closes, the more the mix and the lower the temperature of the direct heat carrier of the heating system and, accordingly, 5

0

0

five

but, the return temperature of the subscriber is lower and vice versa.

With an increase in the degree of mixing, the pressure differential of the heating system and the differential pressure regulator 2 begin to grow. The switch 13 by means of the actuator 3 begins to cover the control valve 4, restoring the predetermined differential pressure in the heating system.

When the temperature of the subscriber's return heat medium is lower than the ipa-Fika heat network at a given temperature of the heat source direct thermal power station, the difference regulator 15 through the pulse interrupter 14 by means of the actuator 10 begins to pulse the control valve 9 of the submode, reducing the flow of the return heat source to the system input. heating Upon further (lowering the temperature in heated rooms, valve 9 is opening more and more open. When it is fully opened, the limit switch 18 opens, which turns off the pump 7 drive 6 of the kneading pump. As a result, the check valve 23 is closed, h; this eliminates direct heat flow Yositel heating network in the return line of the subscriber.

When the hot water intake changes, the proportion of cold water intake changes and, as a result, the temperature of the hot water changes. Therefore, the temperature controller 1 through the switch 13 by means of the mechanism 12 changes the position of the three-way valve 11 so as to change the amount of the direct heat carrier of the CHP plant passing through the second stage B of the DHW heater. With a decrease in the temperature of the hot water supply system, the three-way valve 11 increases the proportion of the direct heat carrier t passing the preheater through the second stage B, and reduces it bypassing it. As the temperature of the DHW increases, the valve 11 moves in the opposite direction.

When the three-way valve 11 is moved while adjusting the DHW temperature, the total amount of heat carrier supplied to the heating system input through the valve 19 remains practically unchanged and the pressure drop remains unchanged, i.e. the temperature regulling process IB does not have a disturbing effect on

0

five

0

five

0

five

0

five

The process of re-controlling the pressure differential of the heating system, which leads to the stabilization of the entire sig gems of automatic regulation.

Thus, a new set of distinctive features due to the stabilization of the adjustable parameters provides the proposed CAP with high quality indicators.

Analogue thermocouple 16 (figure 1) works as follows. Thermocouples 24 and 25, for example, of the TOG calibration type SOOG, measure the temperature of the direct heat carrier of the CHP, for example, 94 ° C, and convert each of them into resistance of 136.799 Ohms. Since both thermoelectric converters 24 and 25 are connected in series and in parallel to both of them, a resistor 26 of 211.48 Ohms is connected, the thermal converter 16 eventually has a resistance of 119.28 Ohms, which corresponds to a temperature of 49 ° C, i.e. such that the return heat carrier of the subscriber should have according to the heating schedule at the direct heat carrier of CHP 94 ° C. In a similar way, the temperature of the direct heat carrier of CHP will be converted from 70 to 150 ° C.

Claims (1)

Invention Formula A system for automatic control of subscriber input of the heating system, including two stages of a hot water preheater in series, containing a hot water temperature controller, a pressure differential controller in the direct and reverse heat carrier pipes connected to the actuator of the control valve of the differential pressure of the heat carrier, a circulating pump and a mix pump with an actuator connected to the control unit, and a mix control valve with an actuator, characterized in that, in order to improve the quality of regulation, the system additionally contains a three-way valve with an actuator, a switch for the winter and summer control modes, a pulse interrupter and a temperature difference controller with an analog thermocouple of the direct heat carrier temperature to the return heat carrier according to the heating Graph and with the temperature sensor back to the coolant, the differential pressure regulating valve is installed to the second stage of the preheater and connected to the outlet of the three-way valve, the outputs of which are connected respectively to the inlet and outlet of the second stage of the water supply heater; parallel to the submode pump, the actuator of the submode valve is connected to the output of the temperature difference controller via a pulse interrupter, the pump drive is mesa is connected to a control unit via a limit switch complete fyu.2 open the mixing valve, and the actuator of the differential pressure regulating valve is connected to the differential pressure regulator via a winter and summer control switch, set to winter mode, and additionally connected through a winter and summer control switch set to summer mode, to the temperature regulator the hot water supply, the actuator of the three-way valve is connected to the hot water supply temperature controller via a winter and summer switch imov, set to winter mode.