RU2746638C1 - Heating system of building of dependent connection with organization of pulsating mode of heat carrier movement in it - Google Patents

Abstract

FIELD: heat power engineering.

SUBSTANCE: invention relates to the field of heat power engineering, it can be used for heat supply of residential and public buildings and industrial premises. The heating system of the dependent connection building with the organization of a pulsating mode of the heat carrier movement in it includes heating devices, supply and return pipelines, two single-section membrane pumps consisting of a pumping and working chambers connected by a rigid rod and being the left and right sections of a double-circuit membrane pump. Each section of the double-circuit membrane pump is connected only to its own heating device, which are connected to the pump chambers through the discharge and suction check valves. The system contains measuring heat exchangers. The upper and lower inlet valves and the upper and lower outlet valves are connected to the working chambers of the left and right sections of the double-circuit membrane pump, the connection of which is carried out by a valve switching mechanism rigidly connected to the rod. The system also includes additional supply and return pipelines, valves are installed on the supply pipelines, the opening and closing of which is controlled by bellows temperature regulators located in line with the measuring heat exchangers, parallel to the return pipelines, on the return pipelines, inlet valves are installed.

EFFECT: increased efficiency of heat transfer due to pulsating circulation.

1 cl, 1 dwg

Description

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

An individual heating station with a membrane pump is known, including the supply and return pipelines, two single-section membrane pumps, consisting of a pumping and working chambers, connected by a rigid rod and being the left and right sections of the membrane pump, the mechanical switching mechanism of the shock valves on one side is connected to a rigid rod , and on the other hand - with right and left shock valves, a heater in the form of a plate heat exchanger. A pulse flow distributor is installed at the entrance of an individual heating point, which includes the right and left valves of the pulse flow distributor, the right and left rods of the pulse flow distributor, cams of the pulse flow distributor, not rigidly connected to an electric drive, a supply pipeline is connected to the input of the pulse flow distributor, and its outputs connected to the working chambers of the left and right sections of the membrane pump through the supply nozzles, a second heating device in the form of a plate heat exchanger is additionally introduced, each section of the membrane pump is connected only with its own heater, a heater of the right section is connected to the right section of the membrane pump, to the left section of the membrane pump - the heater of the left section, while the input of the heater of the right section is connected simultaneously to the working chamber of the right section of the diaphragm pump through the right shock valve and the pumping chamber of the right section of the diaphragm pump through s discharge check valve of the right section, the inlet of the heater of the left section is connected simultaneously to the working chamber of the left section of the diaphragm pump through the left shock valve and the pumping chamber of the left section of the diaphragm pump through the discharge check valve of the left section, the outputs of the heaters are connected simultaneously to the return pipeline and, accordingly, to pumping chambers of the right or left sections of the diaphragm pump through the discharge check valves of the recirculation and the suction check valves of the right or left sections (RU 183885, IPC F24D 3/02, publ. 08.10.2018).

Among the disadvantages of this design, it should be noted the limited use (only in heating systems without heat exchangers for hot water supply, the complexity of the control system, as well as a narrow range of regulation of the coolant flow rate, as well as the dependence of the heating system on the pressure in the return pipeline.

The closest in technical essence to the proposed technical solution is a heat supply system, including heating devices, supply and return pipelines, an electric drive, two single-section membrane pumps, consisting of a pumping and working chambers connected by a rigid rod and being the left and right sections of the membrane pump, each section the diaphragm pump is connected only with its own heater, the inputs of the heaters are connected to the pump chambers, respectively, of the right or left section of the diaphragm pump through pressure check valves, the outputs of the heaters are connected simultaneously to the return pipeline and, respectively, to the pump chambers of the right or left sections of the diaphragm pump through the suction check valves of the right or left section, characterized in that it additionally contains two heat exchangers for hot water supply, two regulators for the flow of hot water and two impulse flow distributors with shock valves in the inlet ohm and outlet openings and side outlets connected to a common electric drive and connected in parallel to the supply pipeline, the working chambers of the diaphragm pump are connected to the side outlets of the pulse flow distributors, the inputs of heaters and hot water heat exchangers are connected in parallel to the outlets of the pulse flow distributors through hot water flow controllers water, and the outlets of heaters and heat exchangers for hot water supply are connected to the return pipeline through safety check valves (RU 2716545, IPC F24D 3/00, F24D 17/00 publ. 03/12/2020).

Among the disadvantages of this design, it should be noted that there is no automatic correction of maintaining the temperature of the "return" network water when the external temperature changes and deviations of the schedule of quality regulation of the heating network.

The technical result consists in the most complete use of the potential of the coolant by automatically adjusting the temperature of the "return" network water, improving the heat transfer of heating devices with pulsating circulation of the coolant.

The essence of the invention lies in the fact that the heating system of the building of dependent connection with the organization in it of a pulsating mode of movement of the coolant, including heating devices, supply and return pipelines, two single-section membrane pumps, consisting of a pumping and working chambers connected by a rigid rod and being the left and right sections of a double-circuit diaphragm pump, each section of the double-circuit diaphragm pump is connected only with its own heater, which are connected to the pumping chambers through pressure and suction check valves. The system contains measuring heat exchangers, and the upper and lower inlet valves and the upper and lower outlet valves are connected to the working chambers of the left and right sections of the double-circuit diaphragm pump, the connection of which is carried out due to the valve switching mechanism rigidly connected to the stem, and the system also includes additional supply and return pipelines, valves are installed on the supply pipelines, the opening and closing of which is controlled by bellows temperature regulators located in the same line with the measuring heat exchangers, parallel to the return pipelines, as well as inlet valves are installed on the return pipelines.

The drawing shows a diagram of a heat supply system.

The heating system of the building of dependent connection with the organization of a pulsating mode of movement of the coolant in it, includes heating devices 1, 2, supply 3 and return 4 pipelines, two single-section membrane pumps, consisting of a pumping room 5, 6 and working chambers 7, 8, connected by a rigid rod 9 and being the left 10 and right 11 sections of a double-circuit diaphragm pump. Each section 10, 11 of the double-circuit diaphragm pump is connected only with its own heater 1, 2, which are connected to the pump chambers 5, 6, through the discharge 12, 13 and suction 14, 15 check valves. The system contains measuring heat exchangers 16, 17, and the upper 18 and lower 19 inlet valves and the upper 20 and lower 21 outlet valves are connected to the working chambers 7, 8 of the left 10 and right 11 sections of the double-circuit membrane pump, the connection of which is carried out due to the valve switching mechanism 22 , rigidly connected to the stem 9. Also, the system includes additional supply 23 and return 24 pipelines, valves 25, 26 are installed on the supply pipelines 3, 23, the opening and closing of which is controlled by bellows temperature regulators 27, 28, located on the same line with the measuring heat exchangers 16, 17, inlet valves 29, 30 are installed parallel to the return pipelines 4, 24, as well as on the return pipelines 4, 24.

The heating system of a building of dependent connection with the organization of a pulsating mode of movement of the coolant in it works as follows. Initially, the system is connected to the heating network through the supply pipelines 3, 23 and return pipelines 4, 24. In this case, it is filled with a coolant through the return pipelines 4, 24 by opening the inlet valves 29, 30. After filling the circuit and removing air from it, turn on the heating medium supply in the supply pipelines 3, 23. Depending on the position of the valve switching mechanism 22, the coolant will flow into the left or right heating circuits. The mechanism for switching valves 22 from the rod 9 of a double-circuit diaphragm pump is provided. Suppose that the valve switching mechanism 22 is in a state where its upper inlet valve 18 and upper outlet valve 20 are open, and the lower inlet valve 19 and lower outlet valve 21 are closed. In this position, the coolant from the supply pipeline 3 through the open valve 25 of the bellows temperature regulator 27 will enter the left working chamber 7 of the left section 10 of the double-circuit diaphragm pump, moving the rod 9 from right to left due to the pressure difference in the left pumping chamber 5 and the left working chamber 7 In this case, the cooled coolant will be displaced from the left pumping chamber 5, through the discharge check valve 12 again into the heater 1, and then into the return pipeline 4. The pulsations of the coolant in the heater 1 will improve the heat transfer in it. Along the right parallel circuit, the coolant passes through the measuring heat exchanger 16 and the bellows temperature regulator 27. Depending on the temperature of the waste coolant and the outside air, the bellows temperature regulator 27 will increase or decrease the flow area of the valve 25, and thereby decrease or increase the supply of the coolant. Let us assume that the temperature of the waste heat carrier will be higher than the standard temperature at a given outside air temperature and the bellows temperature regulator 27 will slowly reduce the supply of the heat carrier until it decreases. At a lower temperature of the waste heat carrier, the bellows temperature controller 27 will open valve 25. At the same time, from the right working chamber 8, the right section 11, the double-circuit diaphragm pump, the heat carrier through the open upper outlet valve 20 will be displaced into the heater 2, where it will give heat to the ambient air and then sucked in by the right pumping chamber 6 through the suction check valve 15. As soon as the rod 9 of the double-circuit diaphragm pump reaches the extreme left position, the valve switching mechanism 22 abruptly switches (the lower inlet valve 19 and the lower outlet valve 21 open, the upper inlet valve closes 18 and upper outlet valve 20). Abrupt closure of intake valve 18 will create a water hammer, the back pressure wave of which will be transmitted to the input of the lower arm, which will create an initial impulse of force. Further, the flow of the coolant from the supply pipeline 23 through the open valve 26 of the bellows temperature regulator 28 and the lower inlet valve 19 will enter the right working chamber 8 of the double-circuit diaphragm pump, moving the rod 9 from left to right due to the pressure difference in the right working chamber 8 and the right pumping chamber 6. In this case, the cooled coolant will be displaced from the right pumping chamber 6 through the discharge check valve 13 again into the heater 2, and then along two parallel lines into the return pipeline 24. The pulsations of the coolant in the heater 2 will improve heat transfer in it. Along the left parallel chain, the coolant passes through the measuring heat exchanger 17 and the bellows temperature controller 28. Depending on the temperature of the waste coolant and the outside air, the bellows temperature controller 28 will increase or decrease the flow area of the valve, thereby decreasing or increasing the supply of the coolant. At the same time, from the left working chamber 7, the left section 10 of the double-circuit membrane pump, the coolant through the open lower outlet valve 21 will be forced into the heater 1, where it will give off heat to the ambient air and then be sucked in by the left pumping chamber 5 through the suction check valve 14. Subsequently, the processes will be repeated. In this case, the accuracy of maintaining the temperature in the heating circuit will be determined by the sensitivity of the thermosyphon, which depends on the value of the delay.

The presence of bellows temperature regulators 27, 28 in the circuit will ensure the adjustment of the maintenance of the temperature of the "return" of the supply water with changes in the external temperature and deviations of the quality control schedule in the heating network and thereby ensure a more complete use of the potential of the supply water. For bellows temperature controllers 27, 28 to normally open the regulator deadband is in the range 1 ^{° C,} and the time constant of about 60 seconds, provides reliable mixing of the coolant.

In comparison with the known solution, this invention allows the most complete use of the potential of the heating system and improves the heat transfer of heating devices due to pulsating circulation.

Claims (1)

The heating system of the building of dependent connection with the organization of a pulsating mode of movement of the coolant in it, including heating devices, supply and return pipelines, two single-section membrane pumps, consisting of a pumping and working chambers, connected by a rigid rod and being the left and right sections of a double-circuit membrane pump, each section the double-circuit diaphragm pump is connected only with its own heater, which are connected to the pumping chambers, through pressure and suction check valves, characterized in that the system contains measuring heat exchangers, and the upper and lower inlet valves are connected to the working chambers of the left and right sections of the double-circuit diaphragm pump and upper and lower outlet valves, the connection of which is carried out by means of a valve switching mechanism rigidly connected to the stem, the system also includes additional supply and return pipelines, installed on the supply pipelines valves, the opening and closing of which is controlled by bellows temperature regulators, located in the same line with the measuring heat exchangers, parallel to the return pipelines, as well as inlet valves are installed on the return pipelines.

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