RU2031316C1 - Automated thermal station - Google Patents

Abstract

FIELD: heat power engineering. SUBSTANCE: thermal station has supply and reverse pipe-lines 1 and 2 correspondingly of thermal network, supply and reverse pipe-lines 3 and 4 of heating system, mixer 6. Pipe-lines 1 and 2 are connected by two lintels 8 and 9. The first one is connected with the mixer and is provided with shift pump 10 and control 11; the second lintel is connected with unit 6. Thermal station also has preliminary, the first and the second stages 17, 18 and 19 correspondingly of water heater, hot and cold water pipe-lines 16 and 24, three-way cock 23. Power of heat-transfer carrier may be used in total volume; discharge may be reduced as well as temperature at exit of thermal station due to connecting second stage heat-transfer carrier of water heater to output branch pipe through controlled three-way cock of the second lintel 9 and preliminary stage 17 of water heater. Three-way cock is adjusted by two temperature transducers 13 and 14 which are mounted onto output pipe-line of heat-transfer carrier of the second stage of water heater and reverse pipe-line of heating system. EFFECT: improved efficiency. 1 dwg

Description

 The invention relates to a power system and is intended for use in closed centralized heating systems and hot water supply of cities.

 The aim of the invention is a more complete use of the coolant by simultaneously reducing its flow rate and temperature at the outlet of the heat point.

 The drawing shows a schematic diagram of the proposed automated heat point.

 An automated heat station contains supply 1 and return 2 pipelines of the heating network, supply 3 and return 4 pipelines of the heating system. On the supply pipe 1 of the heating network, a heat carrier flow controller 5 for heating and a mixing device 6 of the heating system 7 are installed. An outdoor air temperature sensor 12 and a heat carrier temperature sensor 15 in the supply pipe 3 of the heating system are connected to the controller 5. The supply pipe 1 is connected to the return pipe 4 by two jumpers 8 and 9. An offset pump 10 and a regulator 11 are installed on the jumper 8, to which the outdoor temperature sensor 12 and the coolant temperature sensor 13 in the return pipe 4 of the heating system are connected. The jumper 9 is connected to the mixing device 6.

 The centralized hot water supply system comprises a cold water pipeline 16, a preliminary 17, a first 18, a second 19 water heater stage, an outlet 24 hot water pipeline. The inlet pipe 20 of the coolant of the second 19 stage of the water heater through the regulator 21 is connected to the supply pipe 1. To the controller 21 is connected a sensor 22 of the hot water temperature in the pipe 24. The outlet pipe 25 of the coolant of the second stage of the water heater is connected through a valve 27 to the supply pipe 1 of the heating network, and through three-way valve 23 at the same time to the jumper 9 and to the input pipe of the coolant preliminary 17 stages of the water heater. A three-way valve 23 is connected to the sensor 13 of the temperature of the coolant in the return pipe of the heating system and the sensor 14 of the temperature of the coolant in the pipe 25 after the second stage of the water heater.

 In addition, the automated heat station contains valves 26-37.

 Automated heat point works as follows.

 In the warm season, the valves 26-30, 32, 34, 36, 37 are open and the valves 31, 33, 35 are closed. The mixing pump 10 is operating. The three-way valve is turned off.

 One coolant stream from the supply pipe 1 of the heating network through the pipe 20 through the controller 21 enters the second stage 19 of the water heater and after the valve 27 is mixed with the second coolant stream passing through the controller 5. Thus, the mixed coolant is sent to the mixing device 6 of the heating system 7. The flow rate of the coolant from the heating network to the second stage of the heater and the heating system is automatically regulated by the regulators 21 and 5 according to the signals of the sensors 22, 12 and 15. The coolant from the return pipe jumper wires 4 to the heating system 9 through ejection mixing device mixes with the coolant received by the nozzle of the device, and sent to the feed conduit 3 of the heating system. If there is a lack of volume of the mixed coolant flow in the supply pipe 1 of the heating network after the regulator 5, to ensure the normal operation of the mixing device and maintain the set temperature of the coolant in the return pipe 4 of the heating system, the mixing pump 10 is turned on. The displacement pump performance is regulated by regulator 11 according to the signals of sensors 12 and 13. The coolant from the return pipe 4 of the heating system sequentially passes the first 18 and preliminary 17 stages of the hot water heater it enters the water supply and return thermal conduit network 2. Cold tap water through the pipeline 16 passes the preliminary, first and second stages of the water heater and enters the pipeline 24 hot water supply.

During the heating season when the outdoor temperature is below -5 ^{° C,} work automated thermal point is as follows. The valves 26, 28-30, 32, 33, 35-37 are open, the valves 27, 31, 34 are closed, the displacement pump 10 is turned off, the three-way valve 23 is turned on.

 The coolant from the supply pipe 1 of the heating network enters through the regulator 5 into the mixing device 6 and the supply pipe 3 of the heating system. The flow rate of the coolant is regulated by regulator 5 according to the signals of sensors 12 and 15.

 The coolant from the supply pipe 1 also enters through the pipe 20 through the regulator 21 to the second stage 19 of the water heater and then goes through the pipe 25 through a three-way valve to the second jumper 9 or to the preliminary stage 17 of the water heater, depending on the temperature of the coolant in the pipelines 25 and 4. If the temperature of the coolant in the pipeline 25 is higher than in the return pipe 4 of the heating system, then the control system of the heating station automatically responds to the signals of the temperature sensors 13 and 14 and rehhodovoy valve 23 closes the coolant flow in a preliminary step the water heater 17 and directs it into the second jumper 9.

 The volume of coolant coming from the second stage 19 of the water heater to the jumper 9 replaces the same volume of coolant from the return pipe 4 of the heating system.

 The coolant from the second stage 19 of the water heater through the pipeline 25 through a three-way valve 23 enters the preliminary stage 17 of the water heater, provided that the temperature of the coolant in the pipe 25 is lower than in the return pipe 4 of the heating system.

 Cold tap water through the pipeline 16 passes sequentially through the preliminary stage 17 of the water heater and is heated by the energy of the heat carrier leaving the second stage 19 of the water heater, through the first stage 18 of the water heater and is heated by the energy of the coolant from the return pipe 4 of the heating system, it is heated through the second stage 19 of the water heater the required temperature with the coolant from the pipeline 1 of the heating network, then the water enters the pipeline 24 of the hot water supply system i. The coolant from the return pipe 4 of the heating system passes the first stage 18 of the water heater and enters the return pipe 2 of the heating network, and part of it enters the second jumper 9 for mixing in the mixing device 6.

 In the summer period, when the heating of buildings is turned off, the work of an automated heating station is as follows. The valves 26, 30, 32, 34, 36, 37 are open, the valves 27-29, 31, 33, 35 are closed. The mixing pump 10 is turned off. The three-way valve 23 is installed in such a position that the coolant flow is directed to the second jumper 9.

 The heat carrier from the heating network enters through the pipeline 20 through the regulator 21 to the second stage 19 of the water heater through the pipeline 25, through the three-way valve 23 into the second jumper 9, through the return pipe 4 of the heating system, through the first 18, preliminary 17 stages of the water heater and returns to the return pipe 2 heat network.

 Cold water through the pipeline 16 sequentially passes the preliminary 17, the first 18 and second 19 stages of the water heater and enters the pipeline 24 of the hot water supply system.

 The flow rate of the coolant from the heating network is regulated by the controller 21 according to the signals of the sensor 22 of the hot water temperature in the pipeline 24.

 An analogue of the invention is a well-known automated group heat point [1] connected to a heat network in a dependent manner. The supply pipe of the heating network is connected by two jumpers to the return pipe of the heating system; a mixing pump is installed on the first jumper cut into the supply pipe of the heating network to the elevator. The hot water heater is turned on in a two-stage sequential circuit.

 This technical solution for the use of heat for heating and hot water supply does not allow rational use of heat from the coolant that has passed the second stage of the heater.

During the cold period of the heating season when the outdoor temperature falls below -5 ^{° C,} the heat medium passed through the second stage heater is again returned to the supply pipe heat network before entry into the nozzle of the elevator, thereby reducing the initial temperature of the coolant supplied from the CHP and increasing its consumption, which contradicts the goal of more complete use of the energy of the coolant while reducing its consumption and temperature at the outlet of the heat point.

 An analogue of the invention is also a well-known thermal point [2], where the first thermal stage is connected by the heating side to the jumper between the supply pipe of the heating network and the return pipe of the heating system, and heated between the additional and second stages of the heater. A mixing pump is included in the jumper. The additional heater stage with the heating side is connected to the supply pipe of the heating system.

 This technical solution ensures good operation of the heating system and hot water supply only in the warm season of the heating season, when the flow of coolant emerging from the second stage of the heater is directed to the supply pipe of the heating network and through the mixing device to the supply pipe of the heating system, and the additional and first stage of the heater provide a deeper decrease in the temperature of the coolant entering the heating system.

During the cold period of the heating season when the outdoor air temperature below -5 ^{° C} said heating unit with an additional stage preheater has the following significant disadvantages in the use of coolant energy:
the temperature of the coolant in the supply pipe of the heating network decreases before the mixing device, the coolant passing through the second stage of the heater;
initial heating of cold tap water in an additional stage of the heater with a high-temperature coolant from the supply pipe of the heating system is uneconomical and contradicts the goal of lowering the temperature of the coolant in the return pipe of the heating network, and not in the supply pipe of the heating system;
lowering the temperature of the coolant in the supply pipe of the heating system at the outlet of the additional stage in the winter period of time complicates the maintenance of the thermal regime in heated buildings;
the option of heating the coolant in the return pipe of the heating system in the first stage of the hot water heater, heated in an additional stage of the heater;
in the first stage of the heater, the coolant temperature decreases in the return pipe of the heating system entering the mixing device, which contradicts the goal;
not used an additional stage of the heater in the summer.

 The closest to the invention in terms of the design solution and the achieved goal is an automated heat point, where the heat carrier passing through the second stage of the heater is supplied into a jumper connecting the supply and return pipes of the heating system with the mixing pump and the flow regulator located on it [3].

 Here, the task of reducing the flow rate of the coolant in the heating network and lowering its temperature at the outlet of the heating point only in the transition period of the heating season was successfully solved.

During the cold period with a decrease in outside air temperature below -5 ^C. said automated thermal point of mixing with the pump mounted on the web has the following significant disadvantages in the use of coolant energy:
the temperature of the coolant in the supply pipe of the heating network in front of the mixer is reduced due to the low temperature of the coolant passing through the second stage of the heater;
the supply of the coolant from the second stage of the heater to the jumper in front of the mixing pump is impractical, since with further pumping of this coolant into the heating system by the pump it leads to unreasonable additional energy costs.

 The aim of the invention is a more complete use of the energy of the coolant while reducing its flow rate and temperature at the outlet of the heat point.

 This goal is achieved by the fact that the second stage of the heater of the hot water supply system with the outlet coolant pipe is connected through a three-way valve to the second jumper and the preliminary heater stage, and the three-way valve has two temperature sensors installed on the outlet pipe of the second stage coolant and the return pipe of the heating system.

This allows you to direct the coolant emerging from the second stage of the heater to the preliminary stage when its temperature is lower than the temperature of the coolant in the return pipe of the heating system, or to the second jumper when its temperature is higher than the temperature of the coolant in the return pipe of the heating system. Introduction into proposed automatic preliminary heater stage preheater allows cold during the heating season when the outdoor temperature is below ^-5 ° C, additional use of coolant energy from the second stage preheater whose temperature is lower than the temperature of the coolant in the return pipe of the heating system, which corresponds to the goal of a more complete use of the energy of the coolant while reducing its flow rate and temperature at the exit of heat vogo point. It should be noted that the use of a hot water supply system of water from surface water whose temperature in winter is 0.2 ... 1 ^C (typical for Siberia and Far East), the relevance of using a preliminary stage increases as compared with the embodiment use of water from underground sources with a temperature of 5 ... 8 ^o C.

 The technical solution for transferring the coolant from the second stage of the heater to the jumper between the supply pipe of the heating network and the return pipe of the heating system through a three-way valve, regulated by temperature sensors, into the suction pipe of the elevator (second jumper) takes into account the case when its temperature is higher than the temperature of the coolant in the return pipe of the heating system . The heat transfer agent from the second heat stage to the specified jumper displaces an equal volume of heat transfer fluid from the return pipe of the heating system, thereby increasing the temperature of the heat transfer medium in the supply pipe of the heating system.

At low negative temperatures of outdoor air in heat points with a constant flow of heat carrier for heat supply and hot water supply in the event of a decrease or temporary cessation of consumer use of hot water (night time, etc.), the application of the invention allows more fully use the energy of the coolant in the heating system. The latter provides a decrease in the temperature of the coolant in the return pipe of the heating system by 6 ... 8 ^o C.

 The return of the coolant with a lower temperature to the centralized heat supply sources (thermal power plants, state district power stations, district boiler houses, etc.) allows more efficient use of the heat capacities of the latter while reducing the required coolant flow rate by 15 ... 20%.

Claims (1)

 AUTOMATED THERMAL ITEM of a heating and hot water supply system, comprising a supply pipe of a heating network with a controller installed on it and connected to a return pipe of the heating system by a first jumper equipped with a mixing pump and a controller having an outdoor temperature sensor, first and second thermal stages of the hot water system heater with inlet and outlet coolant pipelines, characterized in that it has a mixer installed on the supply pipe and a second jumper connected to the last one, the preliminary heat stage of the heater and a three-way valve, the second thermal stage of the heater of the hot water supply system with the outlet pipe of the heating system connected via a three-way valve to the second jumper and the preliminary stage of the heater, the three-way valve has two temperature sensors installed on the outlet pipe coolant of the second heat stage of the heater and the return pipe of the heating system.