RU193051U1 - DEVICE FOR REGULATING WATER TEMPERATURE FOR HEATING SYSTEMS - Google Patents

Abstract

The utility model relates to the field of heat engineering. The essence of the utility model lies in the fact that the device for regulating the water temperature for heating systems, mainly multi-storey buildings, includes a supply and return pipe of a heating unit, while valves, a dirt collector, and a water-jet elevator are installed on the supply pipe of a heating station and on the return piping of the heat point - valves, mud collector, water meter, characterized in that after the water-jet elevator to the feed pipe of the heat point od an additional supply pipe is rigidly connected by its end, and the other end to the main riser of the heating system, in addition, on the additional supply pipe to be able to turn off, turn on and regulate the heating system, there are installed: valves, an electric flow controller, a circulation-mixing pump and a reverse the valve, and the additional return pipe is connected at one end to the return pipe of the heat point, and the other between the flow regulator and the circulation-mixing n Sos to the additional supply line, in addition, said conduit also contains a check valve.

Description

The utility model relates to the field of heat engineering and can be used in the operation of heat exchangers of centralized hot water supply systems and water heating of multi-storey buildings.

At the source (boiler, CHP) of heat, only the qualitative method of regulating the temperature of the water (coolant) is used - by changing the temperature of the outdoor air. However, this method of regulation is not carried out on the entire range of outdoor temperatures (see Vitaliev V.V. et al. “Operation of heating units and heat consumption systems”, M., Stroizdat, 1988, p. 34).

At low outdoor temperatures, quality control is used according to the schedule for heating systems (see Vitaliev V.V. et al. “Operation of heating units and heat consumption systems”, M., Stroizdat, 1988, p. 28). At high outdoor temperatures (in the autumn-spring period) the temperature of the water (coolant) in the boiler room is kept constant and not lower than that required for heating water for hot water supply (usually not lower than 70 ° C for closed systems), see Vitaliev V.V . and others. “Operation of heat points and heat consumption systems”, M., Stroizdat, 1988, p. 26 and in fig. 1.11, d - lines 8, 8 'and 8' '. Therefore, with central quality control according to the heating schedule, local regulation of the heating system in the autumn-spring period is required, and in the absence of local (at the heating point) regulation, an additional heat consumption occurs, that is, overflow.

A device for controlling the temperature of water supplied to the heating system of predominantly multi-story buildings according to the book of V.N. Bogoslovsky, A.N. Scanavi “Heating”, M., Stroyizdat, p. 240-243, fig. 6.16.

In the specified device, temperature control occurs when high-temperature (network) water is mixed with the return (chilled) water of the local heating system. For mixing use a pump that can be installed on the jumper between the heating system highways (see Fig. 6.16, a), on the return line (see Fig. 6.16, 6), or on the supply line (see Fig. 6.16, c )

The disadvantages of the known device: high cost, including capital and operating costs (cost of electrical energy); the need for foundations for pumps (in the case of industrial pumps); the possibility of noise and vibration; high power consumption, etc.

A device for controlling the temperature of water supplied to the heating system according to the book of Andreevsky A.K. “Heating”, Higher School Publishing House 1982. Such a device is a water-jet elevator (elevator), p. 56, fig. 3.2. The main parts of the elevator are the nozzle, suction chamber, neck and diffuser. The high-temperature coolant at the nozzle exit acquires a speed due to which the pressure in the suction chamber is lower than the pressure in the return line of the heating system and some of the return water of the system through the nozzle enters the elevator and mixes with the primary coolant in the neck. In the diffuser, the speed of the mixture decreases, the pressure increases and is brought to the value necessary to overcome the hydraulic resistance of the heating system. Water-jet elevators are installed in heat points.

Known heat point on the book Andreevsky A.K. “Heating”, Higher School Publishing House 1982, p. 56, fig. 3.1. This heat point is taken as an analog. It includes the supply and return piping of the heating unit, while the supply piping of the heating unit is connected at one end to the supply pipe of the heating network and the other end to the main riser of the heating system, the return piping of the heating unit is connected at one end to the return pipe of the heating network and the other end to with a return pipe of the heating system, while valves, a dirt collector, a water-jet elevator are installed on the supply pipe of the heating station, and on the return pipe of the heating station advizhki, sump, water meter. Thermometers and manometers are installed on the heat pipelines of the heat point.

At the specified heat point, the temperature of the water supplied to the heating system is controlled by a water-jet elevator. This is due to the following reasons: the elevator has a large hydraulic resistance, and this increases the hydraulic stability of the heating network; The elevator is simple in design, it has no moving parts, so it is reliable in operation and has a long service life.

However, the efficiency of regulating the water temperature is quite high only at low outdoor temperatures. At high outdoor temperatures (in the autumn-spring period), the efficiency of regulation is extremely small due to the significant waste of heat on heating. The specified cost overrun is especially large in double-pipe heating networks, which simultaneously supply heat to all types of consumers, for example, for heating, centralized hot water supply and ventilation.

The objective of the utility model is to reduce the heat consumption for heating buildings in the autumn-spring period of the year by eliminating overflow, that is, so that the temperature of the water (coolant) supplied to the heating system corresponds to the current outdoor temperature. Using the proposed device for regulating the temperature of the water (coolant) will significantly reduce the consumption of fossil fuels, and the amount of harmful substances entering the atmosphere will also be reduced, that is, the environmental situation will improve.

The essence of the utility model lies in the fact that the device for regulating the water temperature for heating systems, mainly multi-story buildings, includes the supply and return piping of the heating unit, while the supply piping of the heating unit is connected at one end to the supply pipe of the heating network and the other to the main the riser of the heating system, the return pipe of the heating unit with one end connected to the return pipe of the heating network, and the other end to the return pipe of the heating system, and at the same time, valves, a dirt collector, a water-jet elevator are installed on the supply pipe of a thermal station, and valves, a mud-valve, and a water meter on the return pipeline of a thermal point, characterized in that after the water-jet elevator, an additional supply pipeline is rigidly connected to the supply pipeline of the thermal point and one end end - to the main riser of the heating system, in addition, on the most additional supply pipe for the ability to turn off, turn on and regulate the heating system : valves, an electric flow regulator, a circulation-mixing pump and a non-return valve, and an additional return pipe with one end attached to the return pipe of the heating unit, and the other between the flow controller and the circulation-mixing pump to the additional supply pipe, in addition, on the specified the pipeline also has a check valve.

In FIG. Figure 1 shows the heat point of a water heating system connected to a heat network in a dependent manner, part of a heating system (one riser) and two additional pipelines.

The heat point contains supply, return pipelines and a jumper (pipeline). The supply pipe 1 of the heating unit is connected to the supply pipe of the heating network (not shown in FIG. 1), the valves 2 and 3, the sump 4, the water-jet elevator 5 are installed on the supply pipe; the pipeline 1 is connected to the main riser 6 of the heating system, which is connected to the supply line 7, to which the heating riser 8 is connected with the heating devices 9.

The return pipe 10 of the heat point is connected to the return pipe of the heat network (not shown in FIG. 1). Valves 11 and 12 are installed on the pipeline 10, and the return pipeline 10 is connected to the riser 8. A jumper (pipeline) 13 connects the suction chamber of the elevator 5 to the return pipeline 10 and serves to supply the coolant from the return pipeline to the elevator. A dirt collector 14 and a water meter 15 are also installed on the return pipe. Thermometers and manometers are installed on the heat pipelines of the heat point (in Fig. 1, as on the analog, they are not numbered).

The first additional pipeline 16 is connected at one end to the supply pipe 1 after the elevator 5, and the other end is connected to the main riser 6. On the pipeline 16 there are valves (taps) 17 and 18, a flow regulator 19 with an electric actuator 20, a temperature sensor for the coolant (water) 21 , circulation-mixing pump 22 and check valve 23.

The second additional pipe 24 connects the pipe 10 to the pipe 16; a check valve 25 is installed on the pipe 24.

Installation works as follows. Mains water from a heating network with a coolant temperature at design parameters, as a rule, T _g = 150 ° C, passes through a valve 2, a sump 4 and enters a water-jet elevator 5, in which water is mixed from the return pipe 10 (heating system). The admission of the mixed water to the elevator 5 is carried out through the pipe 13. As a result of mixing high-temperature water from the supply pipe of the heating network and water from the return pipe 10, the coolant (water) acquires a temperature t _r with which through pipe 1, it enters the main riser 6, the supply line 7 and riser 8. Then the water passes through the heating devices 9, is cooled to the temperature to, passes the valve 12 and then at point 24 the water flow is divided: part of the water through the pipe 13 is supplied to the elevator 5, and the other part through the pipe 10, hole For a valve 11, a sump 14, a water meter 15, it enters the heat network and then to the source (to the boiler room) for reheating.

In the autumn-spring period, that is, at a high outdoor temperature, when the temperature in the supply pipe becomes 70 ° C (according to the quality control schedule), the valve 3 is closed and the valve 17 is opened, the pump 22 is turned on. Water passes through the valve 17, the flow regulator 19 , the check valve 23 and with the valve open 18 enters the main riser 6, and then into the supply line 7 and then to the riser 8 and heating devices 9, in which it is cooled to the temperature to (return water temperature) and heat enters the return pipe 10 vogo point. At point 29, the return water stream is divided: part of the water through the second additional pipe 24 is sucked up by the pump 22 into the first additional pipe 16, and the other part of the return water at point 26 is again divided: part of the water through the pipe 13 enters the elevator 5, and the other part enters the return pipe of the heating network and returns to the boiler room for re-heating.

Moreover, if the temperature of the coolant (water) does not correspond to the required value for the heating system (for riser 8) according to the quality control schedule, for example, it is higher than required, then the water temperature sensor 21 sends a signal to the electronic unit 27. At the same time, to the electronic unit 27 receives a signal from sensor 28 (outdoor temperature sensor). After that, the electronic unit 27 issues a command to the electric drive 20 of the flow controller 19 and the electric drive 20 covers the cross section for the passage of water through the pipe 16, thereby reducing the flow of water flowing through the pipe 16, and the flow of water from the return pipe 10 through the pipe 24 increases, that is, the temperature coolant is reduced. Thus, the performance of the pump 22 and, consequently, the flow of water in the heating system remains constant.

And vice versa, if the temperature of the water supplied to the heating system has become lower than required, then the sensors 21 and 28 send the corresponding signals to the electronic unit 27, he gives the command to the electric drive 20, which opens the shut-off element of the flow regulator 19 by a large amount and at the same time the flow rate of the network water increases, and the flow rate of the mixed water through the pipe 24 decreases, while the temperature of the water supplied to the heating system increases.

In the heating units of the heat supply system of a city or city, there is a situation where the pressure in the return pipe 10 is lower than the pressure in the supply pipe 1. The pressure in the return pipe 10 must be increased in such a way as shown in FIG. 2: the circulation-mixing pump 22 is installed on the return pipe 30, which is connected at both ends to the return pipe 10, a valve 31 is installed between the connection points on the pipe 10, a valve 32 is installed at the end of one end, and a check valve 33 at the end of the other.

In this case, if the temperature in the supply pipe becomes equal to 70 ° C (according to the quality control schedule), the valves 3 and 31 close and open the valves 17 and 32, turn on the circulation-mixing pump 22. Under the influence of the circulation-mixing pump 22, the heat carrier passes through the valve 17 , a flow regulator 19, a non-return valve 23 and with an open valve 18 enters the main riser 6, and then into the supply line 7, then to the riser 8 and heating devices 9, in which it is cooled to the temperature to (return water temperature). When the valve is closed 31, the coolant enters the pipeline 30 through the open valve 32 and the check valve 33 and enters the return pipe 10 of the heat point. At point 29, the return water stream is divided: part of the water through the second additional pipe 24 is sucked into the first additional pipe 16, and the other part of the return water at point 26 is again divided: part of the water through the pipe 13 enters the elevator 5, and the other part enters the return pipe heat network and returns to the boiler room for re-heating.

Moreover, if the temperature of the coolant (water) does not correspond to the required value for the heating system (for riser 8) according to the quality control schedule, for example, it has become higher than required, then the water temperature sensor 21 sends a signal to the electronic unit 27. At the same time, to the electronic unit 27 receives a signal from sensor 28 (outdoor temperature sensor). After that, the electronic unit 27 issues a command to the electric drive 20 of the flow regulator 19 and the electric drive 20 covers the cross-section for the passage of water through the pipe 16, thereby reducing the flow of water going through the pipe 16, and the flow of water from the return pipe 10 through the pipe 24 increases, that is, the temperature coolant is reduced. Thus, the performance of the pump 22 and, consequently, the flow of water in the heating system remains constant.

And vice versa, if the temperature of the water supplied to the heating system has become lower than required, then the sensors 21 and 28 send the corresponding signals to the electronic unit 27, he gives the command to the electric drive 20, which opens the shut-off element of the flow regulator 19 by a large amount and at the same time the flow rate of the network water increases, and the flow rate of the mixed water through the pipe 24 decreases, while the temperature of the water supplied to the heating system increases.

The above set of features is not currently known from the prior art and does not follow from well-known methods for controlling the temperature of a heat carrier for heat consumption systems (heating system, ventilation, air conditioning, hot water supply, etc.). This proves compliance with the criterion of "inventive step".

The implementation of the proposed device for controlling the temperature of the coolant with the specified set of essential features does not represent any structural, technical and technological difficulties, hence the compliance with the criterion of "industrial applicability". Indeed, when implementing the proposed device, the elevator is not subject to dismantling; due to the high hydraulic resistance of the elevator, the heating networks become hydraulically stable, after the introduction of the proposed device for regulating the temperature of water for heating systems, at least at one or several objects, the adjustment of heating networks is not required.

Thus, the use of the proposed device for regulating thermal energy allows you to:

reduce heat consumption for heating in the autumn-spring period of the year;

improve the quality of life (due to lack of overflow);

the water flow in the heating system at any outdoor temperature remains constant, that is, the heating system does not adjust;

the implementation of the proposed invention allows to introduce in buildings 60-90 years of the last century in parts; at the same time, capital costs will not be high, since in addition you will have to install valves, pipelines, check valves, an electric flow regulator, a circulation-mixing pump, an electronic unit with sensors;

to implement the proposed device, equipment and devices commercially available from industry are used;

To switch from the winter mode of operation of the heating system to the autumn-spring one, it is not necessary to disassemble the heating system and stop the heating system and heating networks.

Claims (1)

A device for controlling the temperature of water for heating systems, mainly multi-story buildings, includes a supply and return pipe of a heating unit, while the supply pipe of a heating unit is connected at one end to a supply pipe of a heating network and the other end to a main riser of a heating system, a return pipe to a heating unit one end connects to the return pipe of the heating network, and the other end connects to the return pipe of the heating system, while on the supply pipe of the heat The valves are installed, a dirt collector, a water-jet elevator, and valves, a mud valve, and a water meter are installed on the return pipe of the heating unit, characterized in that after the water-jet elevator, an additional supply pipe is rigidly connected to the supply pipeline of the heating station and the other to the main riser of the system heating, in addition, on the most additional supply pipe for the ability to turn off, turn on and regulate the heating system installed: valves, flow regulator with electric ohm, the temperature sensor of the coolant (water), the circulation-mixing pump and check valve, in turn, the flow controller with an electric actuator, the temperature sensor of the coolant (water) and the circulation-mixing pump are wired to the electronic unit, and then to the outdoor temperature sensor air, and the return auxiliary pipe is connected at one end to the return pipe of the heating unit, and with the other between the flow regulator and the circulation-mixing pump to the additional supply pipe piping, in addition, on the specified pipeline also has a check valve.

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