RU2756654C1 - Hot water supply system with the organization in it of a pulsating mode of movement of the coolant and heated water - Google Patents

Abstract

FIELD: heat power engineering.

SUBSTANCE: invention relates to the field of heat power engineering and can be used for heat supply of residential and public buildings and industrial premises. The hot water supply system with the organization of a pulsating mode of movement of the coolant and heated water in it includes the supply and return pipelines, two single-section membrane pumps, consisting of left and right pumping and left and right working chambers, rigidly connected by a rod and being the left and right sections of a double-circuit membrane pump. Discharge and suction check valves are connected to the pumping chambers. Additionally, the system contains left and right main heat exchangers, which are connected on one side, respectively, with return and supply pipelines through valves of bellows temperature regulators, upper and lower inlet valves, working chambers, lower and upper outlet valves, inlet valves. In this case, the upper and lower intake valves, the lower and upper exhaust valves are connected with a switching mechanism rigidly connected to the stem. On the other hand, the main heat exchangers are connected to consumers and water pipelines through bellows temperature regulators, suction check valves, pump chambers, left and right sections of a double-circuit diaphragm pump and delivery check valves. Recirculation pipelines are connected in parallel to the water pipelines.

EFFECT: invention makes it possible to use the potential of the heat carrier to the fullest due to the automatic adjustment of the temperature of the "return" network water, the transformation of the pressure from the heating circuit to the heated one, as well as improving the heat transfer of heat exchangers with pulsating circulation of the heat carrier.

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.

A heat supply system is known, including a heat source connected with the supply and return pipelines of the heating network connected to the heat exchanger through a network pump installed on the return pipeline of the heating network, and a heat consumption system with distributing supply and return pipelines connected to the heating network according to an independent scheme through a heat exchanger ... Additionally, the system is equipped with a self-excited hydraulic shock generator, a pulse blower with an elastic diaphragm installed inside and check valves for inlet and the return pipeline of the heating network and from its second side, in series through the inlet and outlet check valves, is connected to the distributing supply or return pipeline of the heat consumption system (RU 98060, IPC F24D 3/00, publ. 09/27/2010.).

Among the disadvantages of this design, it should be noted the relatively complex balancing of the system, the low heat transfer coefficient between high-temperature and low-temperature heat carriers, low reliability of the heating network pump due to periodic hydraulic shocks, the tendency of the heat exchanger to "boil", deposits and sludge due to the lack of control devices and devices. regulation of the parameters of the heating and heated medium, as well as the complexity of the control system.

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 membrane pump are connected to the side outlets of the impulse flow distributors; water, and the outlets of heating devices 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 high-quality regulation of the heating network.

The technical result consists in the most complete use of the potential of the coolant due to automatic adjustment of the temperature of the "return" network water, transformation of the pressure from the heating circuit to the heated one, as well as improving the heat transfer of heat exchangers with pulsating circulation of the coolant.

The essence of the invention lies in the fact that the hot water supply system with the organization in it of a pulsating mode of movement of the coolant and heated water includes supply and return pipelines, two single-section membrane pumps, consisting of left and right pumping rooms and left and right working chambers, rigidly connected by a rod and being left and right sections of the double-circuit diaphragm pump. Discharge and suction check valves are connected to the pumping chambers. Additionally, the system contains left and right main heat exchangers, which are connected on one side, respectively, with return and supply pipelines through valves of bellows temperature regulators, upper and lower inlet valves, working chambers, lower and upper outlet valves, inlet valves. In this case, the upper and lower intake valves, the lower and upper exhaust valves are connected with a switching mechanism rigidly connected to the stem. On the other hand, the main heat exchangers are connected to consumers and water pipelines through bellows temperature regulators, suction check valves, pump chambers, left and right sections of a double-circuit diaphragm pump and discharge check valves. Recirculation pipelines are connected in parallel to the water pipelines.

The drawing shows a diagram of a hot water supply system with the organization in it of a pulsating mode of movement of the coolant and heated water

The hot water supply system with the organization in it of a pulsating mode of movement of the coolant and heated water includes supply 1 and return 2 pipelines, two single-section membrane pumps, consisting of left 3 and right 4 pumping and left 5 and right 6 working chambers, rigidly connected by rod 7 and being left 8 and right 9 sections of a double-circuit diaphragm pump, to pump chambers 3,4, pressure 10,11 and suction 12,13 check valves are connected. Additionally, the system contains left 14 and right 15 main heat exchangers, which are connected on one side, respectively, with return 2, 16 and supply 1,17 pipelines through valves 18,19 of bellows temperature regulators 20,21, upper 22 and lower 23 inlet valves, working chambers 5.6, lower 24 and upper 25 outlet valves, inlet valves 26.27. In this case, the upper 22 and lower 23 inlet valves, the lower 24 and upper 25 outlet valves are connected to the switching mechanism 28, rigidly connected to the rod 7. On the other hand, the main heat exchangers 14,15 are connected to consumers 29,30 and water pipes 31,32, through bellows temperature regulators 20.21, suction 12, 13 check valves, pump chambers 3,4, left 8 and right 9 sections of the double-circuit diaphragm pump and delivery check valves 10.11. Moreover, parallel to the water pipelines 31.32, recirculation pipelines 33.34 are connected.

The hot water supply system with the organization in it of a pulsating mode of movement of the coolant and heated water works as follows. Before starting work, the system is filled from the side of the spent heating medium by opening the inlet valves 26, 27 located on the return pipelines 2.16. After filling the system with heating medium and removing air from it, the heating medium is supplied in the supply pipe 1 and 17. Depending on the switching mechanism of the valves 28, the heating medium will enter the left 14 or right 15 main heat exchanger. The valve switching mechanism 28 is provided from the stem 7. Suppose that the valve switching mechanism 28 is in a position where its upper inlet valve 22 and upper outlet 25 are open, and the lower inlet 23 and lower outlet 24 are closed. In this position, the coolant from the supply pipeline 1 through the open valve 18 of the bellows temperature regulator 20 will enter the left working chamber 5 of the double-circuit diaphragm pump, moving the rod 7 from right to left due to the pressure difference in the left 5 and right 6 working chambers. In this case, the heated water from the recirculation pipeline 33 and the water pipeline 31 located in the left pumping chamber 3 will be displaced into the left main heat exchanger 14, through the pressure check valve 10. In the left main heat exchanger 14, a portion of the mixed heated water will be heated to a predetermined temperature and enter the network consumer 29. At the same time, from the right working chamber 6, the heating medium through the open upper outlet valve 25 will be displaced into the right main heat exchanger 15, where it will give heat to the heated water. In this case, heated water mixed from the water supply 32 and the recirculation pipeline 34 through the bellows temperature regulator 21, the suction check valve 13 enters the right pumping chamber 4. After the rod 7 reaches the extreme left position, the switching mechanism of the valves 28 will switch, the upper inlet 22 and the upper the outlet 25 valves will close, and the lower inlet 23 and lower outlet 24 valves will open. With this position of the valves, the heating coolant from the supply pipeline 17 through the open valve 19 of the bellows regulator 21 will enter the right working chamber 6 of the double-circuit diaphragm pump, moving the rod 7 from left to right due to the pressure difference in the right 6 and left 5 working chambers. In this case, the mixed heated water from the water pipeline 32 and the recirculation pipeline 34 located in the right pumping chamber 4 will be displaced through the discharge check valve 11 into the right main heat exchanger 15, in which it will be heated to a predetermined temperature and sent to the consumer 30. At the same time, mixed from water pipe 31 and recirculation pipe 33, heated water through the suction check valve 12 will be sucked into the left pumping chamber 3.

With an increase in the analysis of the heated water at the consumer 29, the temperature of the mixed heated water will decrease and the bellows temperature controller 20 will slightly open the valve 18, increasing the flow rate of the heating medium. With an increase in the flow rate of the heating coolant, the pressure at the inlet of the working chamber 5 will increase, which will lead to an increase in the speed of the rod 7, and, consequently, an increase in the flow rate of heated water directed to the consumer 29.

As a result of using this design of the hot water supply system with the organization in it of a pulsating mode of movement of the coolant and heated water, overheating of the spent heating medium is excluded, booster pumps in front of the heat exchangers are not required, heat transfer is improved and deposits on the heat transfer surfaces of the heat exchangers are reduced.

Claims (1)

A hot water supply system with the organization in it of a pulsating mode of movement of the coolant and heated water, including the supply and return pipelines, two single-section membrane pumps, consisting of left and right pumping and left and right working chambers, rigidly connected by a rod and being the left and right sections of a double-circuit membrane pump, discharge and suction check valves are connected to the pumping chambers, characterized in that the system additionally contains left and right main heat exchangers, which on one side are connected, respectively, with return and supply pipelines through valves of bellows temperature regulators, upper and lower inlet valves, working chambers , lower and upper outlet valves, inlet valves, while the upper and lower inlet valves, lower and upper outlet valves are connected to a switching mechanism rigidly connected to the stem, on the other hand, the main heat exchangers are connected to consumers and water ducts, through bellows temperature regulators, suction check valves, pumping chambers, left and right sections of a double-circuit diaphragm pump and discharge check valves, and recirculation pipelines are connected parallel to the water pipelines.

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