RU2415348C1 - Automatic control method of heat load of building, and device for its implementation - Google Patents

Abstract

FIELD: heating.

SUBSTANCE: automatic control method of heat load of building of closed heat supply system with dependent connection of subscriber connections of heating system circuit through water-to-water elevator involves the support of the specified heat load of building considering actual ambient air temperature. At that, heat load is controlled by the appropriate change of water flow through heating system depending on momentary change of weather conditions below breakpoint of temperature chart with change of injection of elevator and in addition with correcting pump at operation of heat supply system above breakpoint of temperature chart. Also, automatic control device of heat load of building is described.

EFFECT: higher accuracy of maintaining the specified temperature conditions of the building.

4 cl, 1 dwg

Description

The invention relates to a power system, in particular to a heat supply, and can be used in closed heat supply systems of predominantly residential buildings with a dependent scheme of connection to a heat network.

A known method of automatically controlling the combined heat load of a heat point in an open heat supply system with the dependent connection of risers of the circulating circuit of a hot water supply system, heating ventilation and a water-elevator heating system, equipped mainly with a commercial metering unit for thermal energy, including maintaining within the values determined by the actual mode of operation district heating systems, standard water temperature for hot water equipment and the required air temperature in heated rooms, characterized by the fact that they change the amount of heat entering the heating system and the hot water risers according to the absolute current temperature of the outdoor air, and maximize the implementation of the heating schedule at the outlet of the heating system with an uncontrolled increase in the flow rate of hot water for domestic needs and the changing load of heating ventilation (RU 2320928, IPC F24D 3/02, publ. 2008.03.27).

A device is known for automatically controlling the combined heat load, comprising a mixing pipe located between the supply and return pipelines of the network water, on which a mixing centrifugal pump equipped with an adjustable drive and a spring check valve are installed, and the network water supply valve to the heating ventilation system is installed at a distance of at least 6 the diameters of the supply pipe to the insertion point along the coolant of the mixing pipeline (RU 2320928, IPC F24D 3/02, о publ. 2008.03.27).

The disadvantage of the known solutions is the following: when connecting heating units to the heating network in a dependent scheme with an elevator, in case of a decrease in water flow in the heating system, the temperature difference in the heating devices increases and the gravitational difference increases, which leads to a vertical misregistration of the heating systems. This circumstance limits the use of quantitative regulation in such systems. In addition, this regulation does not simultaneously take into account the instantaneous influence of all actual weather conditions (outdoor temperature, wind speed, its direction, solar radiation), as well as network water parameters. All this leads to overshoot, and consequently, to a decrease in the accuracy of maintaining the given thermal regime of the building.

The technical result is to increase the accuracy of maintaining a given temperature of the building.

The essence of the invention lies in the fact that in a method for automatically controlling the heat load of a building of a closed heat supply system with the dependent connection of subscriber inputs of the heating circuit through a water-elevator, including maintaining a given heat load of the building taking into account the actual temperature of the outdoor air, the heat load is controlled by a corresponding change in flow water through the heating system, depending on the instant change in weather conditions below the temperature break point the graph by changing the injection of the elevator and an additional corrective pump during operation of the heat supply system above the break point of the temperature graph. Maintaining a given thermal load of the building is carried out by changing the throughput of the expansion valve using the thermal energy of the return network water at the outlet of the heating system. Maintaining a given thermal load of the building is carried out in accordance with the instantaneous value of changes in weather conditions, for example, the absolute temperature of the outside air, solar radiation and wind speed.

In the device for automatically controlling the heat load of the building, including the supply and return pipelines of the heating system water network with a water-and-water elevator, as well as a mixing pipeline located between the supply and return pipes, a thermal expansion valve with a heat-sensitive element at the outlet is installed on the mixing pipeline of the water-water elevator a heat exchanger included in the mixing pipe through the flow controller "after itself" parallel to the expansion valve and them guide in direct contact with the environment, wherein between the feed and return water pipes in the network portion to pressurized water elevator is a correction motor pump associated with the thermal expansion element, and a check valve mounted on the pump output correction.

A schematic diagram of a heating system that implements the proposed method is presented in the drawing.

The device includes a supply 1 and return 2 pipelines of network water of the heating system 3 with a water-elevator 4, as well as a mixing pipe 5, located between the supply 1 and return 2 pipeline. On the mixing pipeline 5 of the water-water elevator 4, a thermal expansion valve 6 is installed with a heat-sensitive element 7 at the outlet of the heat exchanger 8, which is connected to the thermal expansion valve 6 in parallel to the thermal expansion valve 6 and having direct contact with the environment through the after-flow controller 9. Between the supply 1 and return 2 pipelines of network water in the area to the water-elevator elevator 4 is a correction pump 10, equipped with an electric actuator 11, connected to a thermal expansion element, and also a check valve 12 installed at the output of the correction pump.

The regulation method is as follows.

The heat supply system 3 is configured to pass the required flow rate of the coolant. The water-water elevator 4 of the heat supply system 3 is selected to create the necessary pressure to overcome the hydraulic resistance of the heat supply system 3 in such a way that its calculated mixing coefficient is ensured when the injection margin is determined by the corresponding position of the expansion valve 6 in the mixing pipe 5 of the water-water elevator 4. Corrective the pump 10 is in the off state, while the check valve 12, installed at its outlet, prevents the current of high temperature the carrier fluid from the supply pipe 1 to the return 2, bypassing the heat supply system 3. The temperature of the supply water at the outlet of the heat exchanger 8, partially selected in a constant amount determined by the flow regulator "after itself" 9 from the mixing pipeline 5 of the water-water elevator 4, is taken as an informative parameter , which, due to the direct contact of the heat exchanger 8 with the environment, reflects the real dependence of the heat loss on the actual changes in weather conditions (outdoor temperature, wind axis, its direction, solar radiation) at their significant rate of change relative to the heat loss of the building, being cooled in the heat exchanger 8 by Δt ° C and fixed by the heat-sensitive element 7 of the thermal expansion valve 6. By the condition of ensuring the optimal thermal regime at the outlet of the heat exchanger 8, which simulates the system heat supply 3 with its own heat loss, but with a significantly lower delay under any changes in meteorological conditions (outdoor temperature, wind speed, its pressure regulation, solar radiation) the temperature of the coolant must remain constant. If the given temperature of the return network water under the actual weather conditions will correspond to the given heat load of the building under the same weather conditions, then the thermal expansion valve 6 will be opened by 85-90%, which corresponds to its normal position, while the heat supply system of building 3 operates in normal mode. The mixing coefficient of the water-water elevator 4 optimally covers the thermal load of the building without any corrective actions, the automatic control system is in the tracking mode. As soon as an external disturbance arises, for example, an underestimation of the temperature of the network water relative to the quality control schedule, the wind speed is too high, relative to the calculated value, which leads to a decrease in the temperature of the network water in the return pipe and, consequently, to a violation of the building’s thermal regime, then losses of the heat exchanger 8 into the environment Δt of the network water on it instantly increases, which is fixed by the thermal expansion element 7. The latter, acting on the thermal expander The 6th valve 6 of the automatic control system covers the flow area of the mixing pipe 5 of the water-water elevator 4, thereby reducing its injection, and therefore the mixing coefficient, as a result of which the temperature of the supply water in the return pipe 2 increases and the temperature of the building stabilizes to normal .

If the result of external influences, for example, is overestimated, relative to the quality control schedule, the temperature of the supply water, increased solar radiation, leads to an increase in the temperature of the supply water in the return pipe 2, and therefore the temperature of the building, then as a result of underestimated heat losses of the heat exchanger 8 environment, Δt of network water on it instantly begins to tend to zero, which is fixed by the thermal expansion element 7. The latter, acting on the thermal expansion valve 6 of the automatic mathic regulation opens the flow cross section of the mixing pipe 5 of water-water silo 4, thereby increasing its injection, and hence, the mixing ratio, whereby the temperature of the heating water in the return pipe 2 of the building is reduced and the temperature is stabilized to normal mode. Under conditions when the temperature of the supply water in the return pipe 2 is still higher than the normative value for a given outdoor temperature, which is also fixed by the heat-sensitive element 7 at the outlet of the heat exchanger 8, and the thermal expansion valve 6 has completely chosen the possibility of increasing the mixing coefficient of the water-water elevator 4, in the operation includes a correction pump 10, the electric actuator of which 11 has a feedback with the temperature-sensitive element 7 of the expansion valve 6. The correction pump 10, additional о mixing in the coolant from the return pipe 2 to direct 1, reduces the temperature of the coolant in the return pipe 2 to the standard values, and brings the temperature of the coolant at the inlet to the heat supply system 3 to sanitary standards, after which it automatically turns off by eliminating the additional temperature effect of the network water on the heat-sensitive element 7 of the expansion valve 6 associated with the electric drive 11 of the pump 10.

The proposed method and device for controlling the heat load takes into account the following operating conditions of a closed district heating system:

- the mismatch of the network water parameters with the current outdoor temperature caused by transport delay of the coolant;

- a change in the hydraulic resistance of individual subscribers of the heating network leads to a destabilization of the hydraulic regime of the entire network;

- correction of the heat load of the building depending on the actual weather conditions (outdoor temperature, wind speed, its direction, solar radiation);

- the occurrence of the “overflow” effect during the operation of the heat supply system below the break point of the temperature graph in the autumn-spring periods;

- the initial discrepancy between the mixing coefficient of the elevator unit and the real heat load, because on the basis of existing calculation methods it is accepted with a margin of up to 15% of the nominal.

Compared with the known solutions, the proposed one provides an increase in the efficiency of regulating the heat load due to the rational use of the heat carrier to ensure a given heat load and completely eliminate the possibility of overheating of network water in the return pipe, and the set heat load is carried out depending on actual changes in weather conditions (air temperature, speed wind, solar radiation). The reliability of the present method is confirmed by the fact that for its implementation there is no need to use electronic control devices, and since the correction pump is switched on only at critical parameters of the coolant, its periodic mode of operation affects the reduction of energy consumption.

Claims (4)

1. A method for automatically controlling the heat load of a building of a closed heat supply system with the dependent connection of subscriber inputs of the heating system circuit through a water and water elevator, comprising maintaining a predetermined heat load of the building taking into account the actual outdoor temperature, characterized in that the heat load is controlled by a corresponding change in water flow through heating system, depending on the instant change in weather conditions below the point of break in the temperature graph by changing engineering elevator section and optionally with a correction pump during operation of the heat supply system above the point of break in the temperature graph. 2. The method according to claim 1, characterized in that the maintenance of a given thermal load of the building is carried out by changing the throughput of the expansion valve using the thermal energy of the return network water at the outlet of the heating system. 3. The method according to claim 1, characterized in that the maintenance of a given thermal load of the building is carried out in accordance with the instantaneous value of changes in weather conditions, for example, the absolute temperature of the outside air, solar radiation and wind speed. 4. A device for automatically controlling the heat load of a building, including the supply and return pipelines of the network water of the heat supply system with a water-water elevator, as well as a mixing pipe located between the supply and return pipes, characterized in that a thermal expansion valve is installed on the mixing pipeline of the water-water elevator with a thermosensitive element at the outlet of the heat exchanger included in the mixing pipe through the flow controller "after itself" in parallel with the thermor an expansion valve and having direct contact with the environment, while between the supply and return pipelines of the mains water, a correction pump with an electric actuator connected to the thermal expansion element is located in the area up to the water-elevator elevator, as well as a check valve installed at the outlet of the correction pump.