RU2674713C1 - Heat carrier parameters regulation system on the heat supply source depending on the internal air temperature at consumers - Google Patents

Abstract

FIELD: heat power engineering.SUBSTANCE: invention relates to the heat power engineering, and can be used for heat supply of residential and industrial buildings. Heat carrier parameters regulation system at the heat supply source is characterized by the fact, that it includes the heat energy consumer, heat energy source and the pipelines heat network communicated to the heat energy consumer and the heat energy source via the heat carrier, at that, the pipelines heat network includes the boiler circuit and the heat network circuit, containing direct and return pipelines, heat energy consumer contains the heat point control room, temperature sensors, pump, the electric driven three-way mixing valve and at least one heat receiver, and the heat energy source includes the boiler room control cabinet, pressure sensors, heat network circuit pumps with variable frequency drives, three-way mixing valves with electric drives, hydraulic separator, the boiler circuit pump, the burner and the hot water boiler.EFFECT: technical result of the claimed invention is reduction in the of fuel and energy resources consumption of both electricity and boiler and furnace fuel, increase in the boiler equipment efficiency and the heat supply system reliability.3 cl, 1 dwg

Description

The invention relates to the field of power engineering and can be used for heat supply of residential and industrial buildings.

The prior art sources of heat supply (boiler rooms, thermal power plants), operating depending on the outdoor temperature according to the temperature schedule.

The disadvantage of such heat supply systems is the inability to accurately maintain the required temperature in the premises of consumers, completely eliminating “overflows”.

The prior art system of heat supply and / or hot water supply of a complex consumer (RU 2364798 C2, published on 08.20.2009) including local consumers in the form of separate buildings or structures, a distribution network of pipelines connected via a heat carrier with a heat source, for example a boiler room, a heat source power plant, thermal power plant, boiler room, shut-off and control valves, pumping equipment, temperature sensors and an automatic control cabinet for starting the electric motor.

The disadvantage of this heat supply system is the inability to control the speed of the pump motor due to changes in pressure on consumers while maintaining a given temperature inside the building.

The technical problem to be solved by the claimed invention is aimed at providing the ability to maintain a given temperature of the air inside the building at the consumer of thermal energy due to the optimal use of boiler equipment.

The technical result of the claimed invention is to reduce the consumption of fuel and energy resources, both electricity and boiler oil, increasing the efficiency of boiler equipment and the reliability of the heat supply system.

The problem is achieved by the fact that the proposed system for controlling the parameters of the heat carrier at the heat supply source, depending on the air temperature at the consumer, includes: the heat energy consumer, the heat energy source and the heat supply network of pipelines communicated through the heat carrier with the heat energy consumer and the heat energy source, at In this case, the heating network of pipelines includes a boiler circuit and a circuit of a heating network containing direct and return pipelines, a consumer of heat energy GII contains a control cabinet for a heating unit, temperature sensors, a pump, a three-way mixing valve with an electric actuator and at least one heat sink, and the heat source contains a control room for a boiler room, pressure sensors, pumps for a heating circuit with frequency-controlled actuators, three-way mixing valves with electric drives, hydraulic divider, boiler circuit pump, burner and hot water boiler.

The development and refinement of the invention are the following features:

- pressure sensors are installed on the direct and return pipelines.

- the consumer of thermal energy is a building, or structure, or industrial enterprise.

The claimed invention is illustrated in the drawing, where in FIG. a schematic diagram of a system for controlling the parameters of a heat carrier at a heat supply source depending on the internal air temperature is presented.

In the drawing, the following notation:

1 - thermal energy consumer;

2 - temperature sensor;

3 - heat receiver;

4 - control cabinet of the heating unit;

5 - three-way mixing valve;

6 - pump;

7 - a source of thermal energy;

8 - pressure sensors;

9 - variable frequency drive;

10 - hydraulic divider;

11 - boiler control cabinet;

12 - burner;

13 - hot water boiler;

14 - direct pipeline;

15 - return pipe.

The control system for the parameters of the coolant at the heat supply source includes:

- a consumer of thermal energy 1, comprising temperature sensors 2, a pump 6, providing a constant flow rate of the coolant in the heating system, a control cabinet for the heating unit 4, a three-way mixing valve 5 with an electric actuator to ensure the coolant is mixed from the return line 15 and heat receivers 3;

- a source of thermal energy 7, containing pressure sensors 8 on the straight line 14 and the return line 15 of the heating network, pumps 6 of the heating circuit with variable frequency drives 9, a three-way mixing valve 5 with an electric actuator to maintain a given temperature regime of the heating network, a hydraulic separator 10 for the organization of two coolant circuits - the boiler circuit and the heat network circuit, the pump 6 of the boiler circuit to maintain a constant flow of coolant, a three-way mixing valve 5 with an electric actuator for dderzhaniya predetermined temperature schedule boiler, the boiler control cabinet 11, the burner 12, the boiler 13;

- a heat network of pipelines communicated through a heat carrier with a heat energy consumer 1 and a heat energy source 7, including a boiler circuit and a heat network circuit, which, in turn, includes a direct 14 and a return 15 pipelines.

Consumers of thermal energy 1 can be buildings, structures and industrial enterprises. In this case, temperature sensors 2 are installed in various places inside the building (structure, industrial enterprise).

The source of thermal energy 7 can be a structure in which a heat carrier (working fluid, usually water) is heated for a heating system, for example, a boiler room or a modular boiler room.

The heat sink 3 may be a device designed to receive, absorb heat, for example, a heating radiator.

The regulation of the parameters of the coolant depending on the temperature of the air of consumers of thermal energy in case of temperature increase is as follows.

The temperature control of the consumer of thermal energy 1 is carried out at three points by means of temperature sensors 2, combined with humidity sensors (not shown in Fig.) Installed in various places of the buildings, determined by instrumental measurements during the pre-project examination.

The duty heating mode is possible to reduce the temperature in buildings on weekends and holidays, at night if there is no need to find personnel at this time.

When the temperature of the consumer of thermal energy 1 is higher than the set value, the temperature sensor 2 is activated, which sends a signal to the control cabinet of the heat point 4, while the coolant is mixed from the return pipe 15 by means of a three-way mixing valve 5 with an electric actuator, which is connected to the thermal control cabinet paragraph 4, by reducing the flow of coolant through a direct pipeline 14.

At the same time, due to the pump 6, the heat carrier is proportionally taken from the return pipe 15 and mixed into the straight pipe 14, which, while maintaining the hydraulics of the heating system (constant flow rate of the heat carrier in the heating system), leads to the required decrease in the temperature of the heat carrier entering the heat sinks 3 ( in heating radiators).

Accordingly, the pressure increases on the direct pipeline 14 at the entrance to the consumer of thermal energy 1 and, as a result, the pressure drop in the circuit of the heating network at the outlet of the heat energy source 7 increases.

The control system of the differential pressure of the heat energy source is a block of comparison (not shown) of interconnected pressure sensors 8 connected to the control cabinet of the boiler 11 and allows you to control the specified differential pressure between the direct 14 and return 15 pipe in the heat network at the outlet of the heat energy source 7.

The signal from the unit for comparing the interconnected pressure sensors 8 is supplied to the control cabinet of the boiler room 11, which, in turn, controls the variable frequency drives 9 of the pumps 6 of the heat network of the heat source 7, while the speed of the electric motor of the pumps 6 of the heat circuit decreases, and as a result, the coolant flow rate is reduced.

To maintain the temperature schedule of the heating network, a three-way mixing valve 5 with an electric actuator is provided, which is connected to the control cabinet of the boiler room 11.

Thus, the network circuit implements not just qualitative, but qualitative and quantitative regulation.

To eliminate the influence of the pressure created by the pump 6 of the boiler circuit, a hydraulic separator 10 was provided on the devices of the heating circuit, which in turn divides the boiler room into two circuits: the boiler circuit and the heating circuit. Pumps 6 of each circuit in this circuit operate independently and do not affect each other.

In the boiler circuit, to ensure the uninterrupted operation of the boiler 13 and to maintain a constant flow of coolant, a pump 6 is installed, i.e. the coolant flow in the boiler circuit exactly corresponds to the capacity of the boilers currently operating. To ensure the required minimum water temperature in the return lines of the boilers and to prevent the formation of condensate, as well as to maintain a predetermined temperature schedule of the boiler, a three-way mixing valve 5 with an electric actuator is installed in the circuit, which is connected to the control cabinet of the boiler 11 in front of the pump 6 in the boiler circuit.

Thus, the highest boiler efficiency is achieved.

With increasing air temperature at the consumer of thermal energy 1, the flow rate of the heat carrier decreases and, as a result, the heat removal from the boiler circuit leads to a decrease in the power of the burner 12 of the boiler 13 and, accordingly, a decrease in fuel consumption.

The reverse situation occurs when the room temperature decreases below a predetermined value, the temperature sensor 2 is triggered, which sends a signal to the control unit of the heat point 4, after which the electric three-way mixing valve 5 with the electric actuator opens, and the mixture of the coolant from the return pipe 15 decreases , respectively, the temperature in the straight pipe 14 increases and, accordingly, the temperature in the room begins to rise. The pressure in the straight pipe 14 decreases when thermal energy 1 is input to the consumer and, as a result, the pressure drop in the heat network at the outlet of the heat energy source 7 decreases.

The signal from the unit for comparing the interconnected pressure sensors 8 is fed to the control cabinet of the boiler room 11, which in turn controls the frequency-controlled drive 9 of the pumps 6 of the heating circuit, increases the speed of the electric motor of the pump 6 of the boiler circuit and, as a result, increases the flow rate of the coolant. The heat removal from the boiler circuit increases, as a result, the power of the burner 12 of the boiler 13 increases to maintain the parameters of the boiler circuit.

The advantages of this system for regulating the parameters of the coolant at the heat supply source are the absence of “overflows” and “underflows” among consumers of thermal energy during operation of the boiler house with maximum efficiency due to:

- maintaining accurate air temperature among consumers of thermal energy;

- the ability to automatically reduce air temperature at night, weekends and holidays;

- constant flow rate of the coolant in the heating system;

- lack of influence of pumps on boilers;

- the operation of the heating network depending on the temperature schedule;

- boiler operation at a constant flow rate;

- maintaining the temperature schedule of the boilers and eliminating low-temperature corrosion of the heating surfaces of the boilers;

- control and management of the entire heat supply system from the workplace of the boiler room operator.

Claims (3)

1. The control system of the parameters of the coolant at the source of heat supply characterized in that it includes a consumer of heat energy, a source of heat energy and a heat supply network of pipelines communicated through the heat transfer medium with a heat energy consumer and a heat energy source, while the heat supply network of the pipelines includes a boiler circuit and a heat network circuit containing direct and return pipelines, a heat energy consumer comprises a control center for a heat point, temperature sensors, a pump, electrically operated mixing valve and at least one heat sink, and the heat source contains a boiler control cabinet, pressure sensors, heat pump circuit pumps with variable frequency drives, three-way mixing valves with electric actuators, a hydraulic separator, boiler circuit pump, burner and hot water boiler. 2. The system according to claim 1, characterized in that the pressure sensors are installed on the direct and return pipelines. 3. The system according to claim 1, characterized in that the consumer of thermal energy is a building, or structure, or an industrial enterprise.

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