RU2827070C1 - Thermal energy distribution loop unit to maintain specified climatic parameters - Google Patents

Abstract

FIELD: heat power engineering.

SUBSTANCE: to ensure balanced heat transfer, the main heat energy distributor comprises a double-circuit pipeline structure of a closed type, along the combined channel connections of which a refrigerant in the form of freon moves, which circulation mode provides for its supply to compressor device, from which vapours of heated freon are supplied to the first heat exchange device made with possibility of condensation of freon vapours with heat release to accumulated water, the reserve of which is used for needs of hot water supply. Freon movement from the first heat exchange device by means of the said channel connections takes place through 3-way valve and 4-way valve installed in series and connected to each other, first of which has a return connection passing through a check valve with a receiver and a subsystem of check valves, and the second of which has a reverse connection to the input of the said compressor device, and also has a connection to the heat machine and to the second heat exchange device, inside which the gas-liquid medium is condensed, giving off heat to the heat carrier serving for technical needs. Subsystem of check valves is combined with a single closed line having an input for connection with said heat machine, an outlet for connection with the said second heat exchanger and an additional connection with the said receiver, which is made through a capillary tube installed on the channel connection with the electric valve, which intensifies the freon flow, which increases the pressure at the inlet of the compressor device.

EFFECT: providing balanced heat transfer.

1 cl, 1 dwg

Description

Field of technology

The proposed invention relates to the field of thermal power engineering and is intended to obtain, in accordance with the temperature conditions of the environment, the desired climatic parameters in the room, which is manifested in the possibility of effective redistribution of the used thermal energy, as well as redirection of the latter in the event of its excess along another circuit, which expands its application and has a positive effect on the resource and energy efficiency of the installation.

State of the art

A heat pump unit for heating and cooling premises is known from the prior art (see RU 2738527, class F25B 30/06, published on 14.12.2020 [1]).

The solution identified from the state of the art relates to thermal energy systems, and in particular to heating and cooling installations for low-rise buildings using low-potential heat sources (outdoor air, soil and groundwater, adjacent land).

The objective of the known heat pump installation [1], according to the concept, is to reduce energy costs and increase efficiency associated with heating and cooling of premises by creating a heating installation that uses two sources of low-potential heat using two different heat exchangers.

As already indicated, the known heat pump installation [1] is used for heating and cooling premises and contains external and internal heat exchange devices, a compressor with an electric drive, four-way valves, as well as connecting pipelines filled with a working fluid (freon) with the possibility of reversing operation due to the presence of the aforementioned four-way valve.

A special feature of the solution known from the state of the art is that an additional heat exchanger is integrated into the freon circuit of the heating unit, connecting the freon circuit with the circuit of the coolant of the ground probes without intermediate coolants. Moreover, the ground probes used consist of plastic pipes filled with liquid coolant, placed in vertical wells. The ground probes are combined into a single circuit using pipes connected to the additional heat exchanger. In addition, the freon circuit of the unit [1] has solenoid valves operating in the "open-closed" mode and which are controlled by an external thermostat.

The following disadvantages should be noted in the solution identified from the prior art [1].

The use of an additional heat exchanger and ground probes can take heat from the ground, which at low outside temperatures will allow the heating system to operate more efficiently, but the installation of these probes requires a number of complex and labor-intensive preparatory works, in particular, including laying a separate circulation circuit connected to the heat exchanger in the form of plastic pipes strictly below the freezing depth, as well as their unification at the bottom of the well by means of a U-shaped connection, which imposes certain restrictions related to the definition and selection of the area, the characteristics of the soil, which should justify the rationality of introducing additional heat and power equipment into the system using low-potential heat from the soil.

The installation of the known heating system is associated with the need for mandatory geodetic work related to determining the characteristics of the soil, drilling vertical wells using drilling equipment, draining groundwater during drilling periods, as well as direct installation of plastic pipes, including their unification and connection to a separate heat exchanger, which causes the presence of an additional disadvantage associated with the long and labor-intensive installation of a system of ground probes, which serves to obtain low-potential heat.

The closest in technical essence to the claimed invention is the heat transfer system known from RU 2337275, class F24D 3/02, published on 27.10.2008 [2].

The solution known from the prior art relates to heat transfer systems, and in particular to systems intended for combined energy production.

The essence of the known solution is connected with the need to create a heat transfer system with increased efficiency and reliability during operation.

A heat transfer system known from the prior art comprises primary and secondary circuits with a moving flow of fluid connected to an energy source and a heat exchanger, wherein the circuits are designed with the possibility of transferring heat.

The known heat transfer system has a primary and secondary circuit designed to transfer heat between the source and the heat load, as well as a feedback pipeline connecting the outlet of the secondary circuit with its inlet by means of a flow of fluid, which creates the possibility of returning the fluid to the inlet of the secondary circuit.

Moreover, the said flow passing through the said feedback pipeline is controlled depending on the indicators characterizing the temperature in the primary circuit, as a result of which it is possible to regulate the temperature of the primary circuit.

As a result, the refrigerant is recirculated in the circuit. At the same time, the efficiency of the heat source is significantly increased if it operates at a high level of heat transfer, and its temperature (the heat source) is maintained at a high and stable level.

Recirculation control allows the primary circuit temperature to be controlled, since it allows the secondary refrigerant temperature to be adjusted and, as a consequence, the difference between the refrigerant temperatures in the primary and secondary cooling circuits.

The following can be noted as disadvantages of the known technical solution [2].

Structurally, the said secondary circuit has a mixing valve, which is usually equipped with control means that receive control signals for regulating and distributing flows. Moreover, the said valve, in particular, can be regulated locally in response to signals from thermometers, as well as remotely, in which case the data on the temperature of the circuits and the heat source are transmitted to the control center, which sends control signals to the said valve for regulating the recirculating flow, however, it should be noted that the permissible variations in the operation of the mixing valve are not uniform and do not actually provide unified technical and operational indicators, in connection with which, at the stage of designing and installing the heat transfer system, depending on external factors and installation features, there arises the problem of selecting and calculating the mode/modes of operation of the secondary circuit, the purpose of which, according to the plan, is to ensure the stability of the flow circulation regardless of the location and conditions of installation, as well as other auxiliary factors affecting the operation.

The known system [2] requires planned maintenance, in particular, including the reception and analysis of data related to the efficiency and performance for a certain period, forecasting the values of the efficiency and performance characteristics, and the said maintenance must be planned so as to avoid conditionally overestimated values of the efficiency and/or performance characteristics. At the same time, it should be taken into account that the specified values can have any value, reaching which the system fails, in particular, in the event of reaching the maximum temperature of the environment, the power plant will immediately begin to overheat, which will have a negative impact on the performance and safety of the system, creating the need for a temporary shutdown of the system for the purpose of cooling and replacing the inoperative module.

Disclosure of invention

The technical problem of the proposed invention is the creation of a thermal energy circuit installation with high technical and operational parameters for distributing and redirecting the used thermal energy in order to maintain optimal climatic parameters in the room.

The technical result of the proposed invention, which solves a current technical problem, is the implementation of the specified purpose of creating a main distributor of thermal energy inside a room, capable of ensuring stable and balanced heat transfer due to the processes of thermal energy distribution that are produced, maintaining relatively stable microclimatic parameters.

The specified technical result is achieved as a result of the fact that the main heat energy distributor for ensuring balanced heat transfer, maintaining stable climatic parameters of the room, contains a double-circuit closed-type pipeline structure, through the combined channel connections of which a refrigerant in the form of freon moves, the circulation mode of which provides for its entry into the compressor device, from which the heated freon vapors enter the first heat exchange device, made with the possibility of condensing the freon vapors with the release of heat, accumulated water, the reserve of which is used for the needs of hot water supply, the movement of freon from the first heat exchange device by means of the mentioned channel connections occurs through a 3-way valve and a 4-way valve installed in series and connected to each other, the first of which has a return connection passing through the check valve with the receiver and the subsystem of check valves, and the second of which has a return connection to the inlet of the said compressor device, and also has a connection to the heat engine and to the second heat exchange device, inside which the gas-liquid medium condenses, giving off heat to the heat carrier, which serves for technical needs, the said subsystem of check valves is united by a single closed line, having an input for connection with the said heat engine, an output for connection with the said second heat exchange device and an additional connection with the said receiver, which is carried out through a capillary tube installed on the channel connection with an electric valve, which increases the flow of freon, which increases the pressure at the inlet of the compressor device.

We offer a technical solution from the field of thermal power engineering, which is a main structure of several circuits of a thermal installation using freon as a refrigerant, which allows obtaining in correlation with the temperature conditions of the environment the necessary heat supply and climatic parameters inside the serviced premises, which becomes possible due to the configured mode of efficient and balanced distribution of the used thermal energy, as well as its redirection in case of excess along the auxiliary circuit, thereby having a positive effect on the efficiency and service life of the thermal power system.

The fundamental feature of the proposed main heat energy distributor for the purpose of ensuring balanced heat transfer is the presence of a circulating dual-circuit system, made in the form of a pipeline structure, through the combined channel connections of which the refrigerant moves in the form of freon, which, in accordance with the inventive concept, passes through a built-in circuit subsystem of check valves, united by a single closed line, and then enters the used heat engine, in which direct evaporation of liquid freon and constant heat intake from the external environment occurs, which, under conditions of a closed mode of circuit operation, contributes to a stable increase in the volumes of pumped heat and stabilization of heat transfer processes, ensuring the constancy and stability of the operation of the thermal system.

In accordance with the key technical feature of the proposed technical solution, the superheated freon vapors have the ability to enter one of the heat exchange devices, where heat is transferred to the accumulated water for the needs of hot water supply, after which the freon is moved through a 3-way valve and a 4-way valve, the first of which has a return connection to the receiver and the check valve subsystem, and the second of which has a return connection to the compressor inlet, and in addition has a connection to the heat engine, as well as to an additional heat exchange device, in which heat is transferred to the coolant, which serves for technical needs associated with heating the premises, at the same time, the essence of the solution also assumes the presence of an input at the existing check valve subsystem for connection to the heat engine, the presence of an output for connection to the said additional heat exchange device, as well as the presence of an additional connection to the said receiver, which is carried out through a capillary tube that enhances the flow rates of freon, which increases the pressure at the compressor inlet and creates conditions for reducing energy consumption, thus as a result of the indicated processes of redistribution of thermal energy and in the case of its "redirection" along the existing auxiliary circuit, it has a beneficial effect on the resource, efficiency and reliability of the system, while ensuring stable and balanced heat transfer, which has the ability to maintain relatively stable microclimatic parameters inside the serviced premises.

It is important to additionally emphasize that the presence of a control subsystem of check valves in the main heat energy distributor allows one compressor device in a kind of single "heat pump" system to switch air-water modes for heating the DHW of the room heating, and the possibility of smooth connection and switching of operating modes in the external block of the heat machine itself is formed depending on the tasks for which the first heat exchange device and the second heat exchange device are called upon. Thus, the design feature of the proposed heat energy distributor allows connecting the first heat exchange device or the second heat exchange device or both at once to work, in addition, it is possible to connect additional heat exchange devices.

Thus, the proposed main heat energy distributor forms a set of technical features sufficient to achieve the specified technical result, which consists in implementing the purpose of creating a main heat energy distributor inside a room, capable of ensuring, due to the processes of heat energy distribution performed, a stable and balanced heat transfer that maintains relatively stable microclimatic parameters, in connection with which a solution is provided to the designated technical problem of creating a heat energy circuit installation with high technical and operational parameters for distributing and redirecting the used heat energy in order to maintain optimal climatic parameters in the room.

Brief description of the drawings

The drawing shows a functional diagram of the proposed heat energy distributor.

Implementation of the invention

The proposed main heat energy distributor for ensuring balanced heat transfer, maintaining the stability of heat supply and the stability of the climatic parameters of the room, is explained by several examples of implementation and implementation, which, however, are not the only possible ones, but clearly demonstrate the achievement of the specified set of essential features of the specified technical result, as well as the solution to the specified technical problem.

The presented drawing shows the following parts and components of the proposed main heat energy distributor:

1 - heat engine with external control unit;

2 - compressor device;

3 - filter;

4 - 3-way valve;

5 - 4-way valve;

6 - receiver;

7 - electronic expansion valve (EEV);

8 - electric valve;

9 - service crane;

10 - capillary tube;

11 - the first heat exchange device for hot water supply;

12 - second heat exchange device for heating/cooling;

13 - check valve;

14 - control subsystem of check valves;

15 - shunt valve;

16 - economizer;

17 - Upper stage ERV.

Thus, the proposed main heat energy distributor for ensuring balanced heat transfer, maintaining the stability of heat supply and the stability of the climatic parameters of the premises contains a double-circuit closed-type pipeline structure.

The specified closed-type structure has combined channel connections through which the refrigerant moves in the form of freon.

The circulation mode of freon movement provides for its entry into the compressor device 2, from which the heated freon vapors enter the first heat exchange device 11.

In turn, the first heat exchange device 11 (heat exchange tank/boiler/storage type boilers in combination with plate or other heat exchangers) is designed with the possibility of condensing freon vapors with the release of heat to the accumulated water, the reserve of which is used for hot water supply and heating needs.

The movement of freon from the first heat exchange device 11 by means of the mentioned channel connections occurs through a 3-way valve 4 and a 4-way valve 5 installed in series and connected to each other.

The specified 3-way valve 4 has a reverse connection passing through the check valve 13 with the receiver 6 and the subsystem of control check valves 14 - they carry out the movement of the refrigerant in one direction, due to their arrangement in the system we obtain the movement of freon condensate in any operating modes through the receiver 6.

The specified 4-way valve 5 has a return connection to the input of the compressor device 2, and also has a connection to the heat engine 1 and to the second heat exchange device 12.

In the heat exchange device 12, the gas-liquid medium condenses, giving off heat to the heat carrier intended for technical needs associated with providing heating to the serviced premises.

The specified control subsystem of check valves 14 is united by a single closed line having an input for connection with the specified heat engine 1, an output for connection with the specified second heat exchange device 12 and an additional connection with the existing receiver 6.

The specified additional connection with the existing receiver 6 is carried out through a capillary tube 10 installed on the channel connection with the electric valve 8, which increases the flow of freon, which increases the pressure at the inlet of the compressor device 2.

It should be noted that the purpose of the presented description of the proposed invention is not to limit its execution and implementation options, but, on the contrary, to be able to cover all sorts of additions that do not go beyond the scope of the invention formula, but explain other acceptable execution/arrangement options according to the author's concept.

The main heat energy distributor for ensuring balanced heat transfer is essentially intended for hot water supply, heating/cooling of the premises.

The proposed heat energy distributor consists of a heat engine 1 with an external control unit with an innovative structure for distributing the flows of the refrigerant - freon, as well as for managing and monitoring the operation.

The specified external control unit of the heat machine 1 has a control controller with the ability to access the Internet.

The configuration of the proposed heat energy distributor is unique and allows the use of equipment to solve a wide range of problems related to heat supply and maintaining the required temperature indicators in the room.

In addition to the heat engine 1, which has an innovative structure for distributing freon flows, the design of the heat energy distributor also includes heat exchange devices 11 and 12, which are designed to supply heat for hot water supply and supply heat for heating needs with the connection of the corresponding circuit with the heat carrier. The design may also include additional heat exchange devices depending on the tasks and technical operating conditions.

In addition, the design of the proposed heat energy distributor includes an economizer 16 and a booster unit in the form of an additional freon pipeline with an ERV 17 built into it (ERV of the booster unit). Moreover, the economizer 16 is installed on the connection that unites the compressor unit 2 and the 4-way valve 5 and is a device that cools the superheated freon condensate and simultaneously heats the supercooled gas after the evaporator (at the suction, the inlet to the compressor unit 2), and the specified booster unit allows the heat engine to quickly enter the operating mode, heating the freon condensate after the existing condenser at the start and during operation, at maximum heat extraction (in the case when the heat extraction exceeds the capacity of the heat engine) does not allow supercooling of the condensate, thereby maintaining the operating mode with nominal effective indicators.

The layout of the heat energy distributor equipment, including additional heat exchange devices, as well as a number of other auxiliary systems involved in the supply of heat and maintaining the required climatic parameters, is selected, among other things, in accordance with the technical tasks set, the size and area of the premises.

The used heat engine 1 with an external control unit communicates with heat exchange devices 11 and 12 via an insulated two-circuit four-pipe main line (pipeline structure), in which freon is located, moving in a closed circulation mode.

Heat exchange devices 11 and 12, depending on the layout and tasks to be solved, can also perform the functions of indirect heating tanks and buffer storage tanks.

In heat exchange devices 11 and 12, in the recirculation mode, heat energy can be transferred from the heat engine 1 to the water inside. Heated water can be supplied to the DHW system, for which purpose there is a corresponding connected water supply pipeline. In a separately connected heating circuit immersed in heated water, a heat carrier circulates, which is heated and used to supply heat in the circulation mode to the heating radiators and/or to the underfloor heating systems. At the same time, cooling is possible through an additional heat exchange device via an additional pipeline circuit of the heat energy distributor, connected to an additionally connected fan coil subsystem for cooling.

The advantage of the proposed main heat energy distributor is based on the use of control valves (3-way valve 4, 4-way valve 5, control subsystem of check valves 14, shunt valve 15), which allows a single compressor device 2 to switch the "air-water" modes for the purpose of heating the DHW and heating the serviced room, in addition, the possibility of smooth switching of operating modes in the outer control unit of the heat machine 1 is ensured.

The proposed main heat energy distributor is implemented as follows.

1. Heating mode of the hot water supply system (DHW)

After entering the compressor unit 2, the heated freon vapors enter the first heat exchange unit 11 for DHW needs, where the freon vapors condense with heat transfer to the water. After the first heat exchange unit 11, the freon in the liquid phase enters the 3-way valve 4. Then, from the 3-way valve 4, the freon enters the receiver 6 through the check valve 13, after which the freon enters the electronic control valve (ECV) 7. Through the system of control check valves 14, the freon enters the external control unit of the heat engine 1, where, in essence, the evaporation of liquid freon and the extraction of heat from the external environment occur.

Then the freon vapors through the 4-way valve 5 enter the input of the compressor unit 2. The electric valve 8 is switched on when the outside air temperature is more than 20°C. And then through the capillary tube 10 it increases the freon flow, thereby reducing the pressure on the high side (at the outlet of the compressor unit 2) and increasing the pressure on the low side (the input of the compressor unit 2). Thus, the current consumption of the compressor unit 2 decreases, but the volume of the pumped refrigerant heat increases, the efficiency of the distributor increases.

The dual-circuit pipeline structure of the heat energy distributor is closed, the operating mode is "air-water" (the second heat exchange device 12 does not participate in the operation).

2. Heating supply mode

After entering the compressor unit 2, the heated freon vapors enter through the shunt valve 15 to the 3-way valve 4. Then from the 3-way valve 4, the freon enters the 4-way valve 5, from which the freon enters the second heat exchange unit 12, in which the freon vapors condense with the release of heat to the coolant used. Then the freon in the liquid phase enters through the subsystem of control valves 14 to the receiver 6.

By means of the subsystem of control check valves 14, freon enters the external control unit of the heat machine 1, where the freon evaporates in a liquid state and the corresponding heat is taken from the external environment. Freon vapors through the 4-way valve 5 enter the input of the compressor device 2.

The electric valve 8 is switched on when the outside air temperature is more than 20°C. And then passing through the capillary tube 10 increases the freon flow, thereby reducing the pressure on the high side (the output of the compressor unit 2) and increasing the pressure on the low side (the input of the compressor unit 2). Thus, the current consumption of the compressor unit 2 decreases, and the volume of the pumped heat increases, in this regard, the efficiency increases.

The dual-circuit pipeline structure of the heat energy distributor is closed (the first heat exchange device does not participate in the operation).

3. Heating mode of the hot water supply system (DHW) + heating provision

After entering the compressor unit 2, the heated freon vapors enter the first heat exchange unit 11 for DHW needs, where the freon vapors condense with the release of heat to the water. After the first heat exchange unit 11, the freon in the liquid phase enters the 3-way valve 4, from which the freon enters the 4-way valve 5, and then into the second heat exchange unit 12. When heating the water for DHW to 55-60°C, the superheated freon vapors do not condense completely, and the resulting gas-liquid medium in the second heat exchange unit 12 is already completely condensed, releasing heat to the coolant.

Next, the freon in the liquid phase enters through the subsystem of control valves 14 into the receiver 6. Through the said subsystem of check valves 14, the freon enters the external control unit of the heat engine 1, where the evaporation of liquid freon and, accordingly, the absorption of heat from the external environment occurs.

Freon vapors through the 4-way valve 5 enter the input of the compressor unit 2. The electric valve 8 is switched on when the outside air temperature is more than 20°C and through the capillary tube 10 increases the flow of freon, thereby reducing the pressure on the high side (the output of the compressor unit 2) and increasing the pressure on the low side (the input of the compressor unit 2). Thus, the current consumption of the compressor unit 2 decreases, and the volume of pumped heat increases, due to which the efficiency increases. The two-circuit pipeline structure of the heat energy distributor is closed.

4. Heating mode of the hot water supply system (DHW) + cooling (heat recovery)

After entering the compressor unit 2, the heated freon vapors enter the first heat exchange unit 11, where the freon vapors condense with the release of heat to the water. After the first heat exchange unit 11, the freon in the liquid phase enters the 3-way valve 4, from which the freon enters the receiver 6 through the check valve 13. From the receiver 6, the freon enters the electronic control valve 7 (ECV).

Through the subsystem of control check valves 14, freon is supplied via service valve 9 to the second heat exchange device 12, where the evaporation of liquid freon and the extraction of heat from the coolant occur.

At the same time, freon vapors, through the 4-way valve 5, enter the input of the compressor unit 2.

The heat energy distributor operates in the "water-to-water" mode, cooling the second heat exchange device 12 - transferring heat to the first heat exchange device 11 for DHW needs.

The dual-circuit pipeline structure of the heat energy distributor is closed.

5. Cooling mode

After entering the compressor unit 2, the superheated freon vapors enter through the shunt valve 15 to the 3-way valve 4. In this case, the 3-way valve 4 switches from one line to another and the freon enters the external control unit of the heat engine 1, where it condenses, accompanied by the release of heat into the environment.

Then, from the external unit of the heat engine 1, liquid freon passes through the subsystem of control check valves 14 to the receiver 6, and then to the electronic control valve 7 (ECV).

Through the subsystem of check control valves 14, freon enters through the service valve 9 to the second heat exchange device 12, in which the evaporation of liquid freon and the extraction of heat from the coolant occur. Freon vapors, through the 4-way valve 5, enter the input of the compressor device 2 (the first heat exchange device 11 does not participate in the operation).

The dual-circuit pipeline structure of the heat energy distributor is closed.

It should be noted that in the heat recovery mode, in the case when both heat exchange devices 11 and 12 are involved in the operation, there is no need for active operation of the external unit of the heat machine 1 simultaneously in two directions.

The key advantage of the proposed technical solution is the ability to redistribute thermal energy in the event of its excess, i.e. its redirection along a secondary (auxiliary) circuit, which ensures a balanced heat transfer, having a positive effect on the operating life.

As a special feature of the proposed solution, it should be noted that the outdoor unit of the heat machine 1 and the compressor unit 2 have their own separate inverter boards, which ensures a smooth start, regulation and high energy efficiency.

The proposed invention can be successfully used in the energy industry as an autonomous system for obtaining heat for the purpose of hot water supply and heating/cooling of premises.

Claims (1)

A main heat energy distributor for ensuring balanced heat transfer that maintains the stability of heat supply and the stability of the climatic parameters of the room, comprising a double-circuit closed-type pipeline structure, through the combined channel connections of which a refrigerant in the form of freon moves, the circulation mode of which provides for its entry into a compressor device, from which heated freon vapors enter the first heat exchange device, made with the possibility of condensing the freon vapors with the release of heat to accumulated water, the reserve of which is used for hot water supply needs, the movement of freon from the first heat exchange device by means of the said channel connections occurs through a 3-way valve and a 4-way valve installed in series and connected to each other, the first of which has a return connection passing through the check valve with the receiver and the subsystem of check valves, and the second of which has a return connection to the inlet of the said compressor device, and also has a connection to a heat engine and to the second heat exchange device, inside which the gas-liquid medium condenses, giving off heat to the heat carrier, which serves for technical needs, the said subsystem of check valves is united by a single closed line, which has an input for connection with the said heat engine, an output for connection with the said second heat exchange device and an additional connection with the said receiver, which is carried out through a capillary tube installed on the channel connection with an electric valve, which increases the flow of freon, which increases the pressure at the inlet of the compressor device.