UA31378U - Heat supply system for premises - Google Patents

Abstract

Heat supply system for premises includes tank-accumulator of hot water to inlet of which solar collectors are connected, season accumulator of heat energy, circulation circuits of heat supply, heat pump, windmill with electric generator, system for automated control of temperature parameters of heat carrier in elements of heat supply system and control of temperature in premises, heat consumer. Input of electric network of power system is connected to drive of heat pump, electric heater of windmill is placed in tank-accumulator for hot water and circulation contours of heat supply connect the consumer of thermal energy to tank accumulator of hot water, season accumulator of thermal energy and heat pump which are connected in parallel to each other.

Description

Description of the invention

The useful model refers to the field of integrated use of renewable energy sources - the sun, 2 wind, Earth's heat, and power grid energy.

A well-known building heating system (patent of Ukraine 3072, MPK5 E2402/142), which consists of solar collectors, a seasonal thermal energy accumulator of a heat consumer, a heat pump, a wind turbine, a circulation circuit and circulation pumps. In the well-known building heating system, all elements of the system are connected in series. 70 This system allows you to combine into a single closed loop the supply of thermal energy from the circuits of accumulation of solar energy, the circuit of conversion of wind energy and heat of the Earth due to the underground accumulation of thermal energy.

The disadvantages of such a system are the sequential connection of the constituent elements of the system by a circulation circuit, which negatively affects the reliability of the system, as well as the lack of control of the temperature parameters of the coolant in 72 elements of the building heat supply system.

The closest analogue of the useful model is the building heating system (patent of Ukraine 64153 MPK7

E2422/02, E24017/00, AO159/24). The known invention contains a heat consumer, solar collectors, a wind turbine with an electric generator, a seasonal thermal energy accumulator, which are connected by circulation circuits with a heat pump and a hot water storage tank, a system for automatic control of the temperature parameters of 20 coolants in the elements of the heat supply system and temperature control in the room . In the adopted version, the wind turbine with an electric generator and the seasonal thermal energy accumulator are connected to the hot water accumulator tank, to which the solar collectors and the heat energy consumer are connected, through the heat pump of the heat supply system.

The disadvantage of this solution is the sequential inclusion of the heat pump in the circulation circuit between the seasonal 25 thermal energy accumulator, the wind turbine and the hot water storage tank, which will lead to an increase in losses in the hot water storage tank due to the increase in the temperature of the water supplied there from the heat pump. In addition, in the prototype, the problem of the operation of the heat supply system of buildings at critical temperatures of the heat carrier in the elements of the seasonal thermal energy accumulator is not resolved - when the temperature of the heat carrier decreases and goes to 090. со 30 The task of the useful model is to improve the system of heat flow distribution from the equipment intended for obtaining , storage and transmission of thermal energy with their mutual backup and improvement of the efficiency and reliability of the seasonal thermal energy accumulator - a system of integrated energy, the use of traditional (power grid energy) and renewable (sun, wind, heat of the Earth) sources of energy 3 by seasonal accumulation for use in the cold period of the year with heating and hot water supply

From household and industrial buildings. with

The task is solved due to the fact that the building heat supply system contains a hot water storage tank, the input of which is connected to solar collectors, a seasonal heat energy storage battery, heat supply circulation circuits, a heat pump, a wind turbine with an electric generator, a system of automatic "control of the temperature parameters of the heat carrier in the elements of the system heat supply and temperature control in the room, the heat consumer, which differs in that it contains the input of the power grid o) s of the power system, connected to the heat pump drive, the electronic heater of the wind turbine, placed in the hot water storage tank, and the circulation circuits of the heat supply connect the consumer thermal energy with a hot water storage tank, a seasonal thermal energy accumulator and a heat pump connected in parallel to each other, in addition, the seasonal thermal energy accumulator structurally consists of 75 several separate sections filled with water, and in the sections installed built-in thermosensors to monitor the water temperature, and the thermal insulation of each section of the seasonal thermal energy accumulator is made with a layer between its inner and outer walls, in which there is a vacuum, in addition, the building heating system is distinguished by the fact that in order to maintain stable indicators of the heat pump supply voltage at about power supply independent of the power grid, an -I 50 electrochemical battery and an inverter are connected to the generator of the wind turbine.

Due to the inconsistency of energy from renewable sources with the needs of the consumer and the instability of its characteristics, the use of energy from renewable sources is most effective in low-temperature processes of space heating. The need to use the energy of the power grid of the power system arises for the drive of power equipment, such as a heat pump compressor, where stable indicators of voltage, 59 power, frequency, etc. are required. This makes it possible to simplify the scheme and reduce the cost of voltage conversion systems for the drive of power equipment, reduce the unit capacity of installations for converting energy from renewable sources into other types of energy, and reduce the cost of equipment for its conversion. Therefore, the use of the power grid of the power system allows for more complete and efficient use of energy from renewable sources while reducing the unit capacity of plants for converting energy from 60 renewable sources and reducing the cost of equipment for its conversion.

The parallel connection of a hot water storage tank, a seasonal heat energy storage tank and a heat pump allows you to use heat for the needs of the consumer of thermal energy, both directly from the hot water storage tank or a seasonal heat storage tank, and from each of these sources through a heat pump , which will allow the use of the heat pump only in the event of a decrease in the water temperature in the hot water storage tank and in the seasonal heat energy storage tank to a level that does not meet the needs of the heat energy consumer.

The execution of a seasonal accumulator of thermal energy, in the form of several sections with a vacuum layer between the inner and outer walls of the sections, allows to reduce non-productive heat losses to the ground, to regulate the selection and supply of heat to each section depending on the water temperature in a separate section, energy production by heat-generating equipment (solar collectors and a wind turbine) and the needs of the heat energy consumer. Thermal sensors installed in the sections of the seasonal thermal energy accumulator allow you to monitor the critical drop in water temperature, control the process of redistribution of thermal energy in the sections and, with the help of the system of automatic control of the temperature parameters of the coolant in elements 7/0 of the system of heat supply and temperature control in the room and taps on the circulation heat supply circuits to direct heat flows to the heat energy consumer.

In the event of interruptions in the power supply, in the event that there is no provision for a backup power supply circuit, in order to maintain stable indicators of the supply voltage of the heat pump when the power supply system is independent of the power grid, an electrochemical battery is connected to the generator of the wind turbine to stabilize and store the current from the generator of the wind turbine and an inverter that allows step up the voltage after the battery and convert direct current to alternating current to power the heat pump drive.

The drawing shows the functional diagram of the building heating system. The system consists of solar collectors (SC) 1, connected by a circulation circuit 2, in which a circulation pump 3 is installed, with a coil 4 located in a hot water storage tank (BA) 5. BA 5 by circulation circuits 6 (points

A1-Ab, B1-Bb), 7 (points At, A2, G1-Gb6, B2, BI) and 8 (points A1-AZ, VI, B2, B1-BZ) is connected, respectively, to the heating element ( NO) 9 heat consumer 10, seasonal thermal energy accumulator (SAT) 11 and evaporator 12 of heat pump (TN) 13. Condenser 14 TN 13 circulation circuit 15 (points VZ, B4, A4 - Ab, B4-Bb) and SAT 11 circulation circuit 16 (points Г2-Г5, АБ, Аб, Б5, Бб) are connected with NE 9 of the consumer about Heat 10. Evaporator 12 ТН 13 and ТАТ 11 are connected with each other by circulation circuit 17 (points Б1, В2, Г1- G6).

Circulation pumps 18, 19, 20 are placed at the entrances to the heat consumer 10, TN 13, SAT 11, and taps 21-42 are arranged on the pipelines - circulation circuits 6-8, 15-17 to regulate the coolant flows. The system of automatic control of temperature parameters of the heat carrier in the elements of the heat supply and temperature control system in the room (ASK) 43 includes thermal sensors 44-47 for control of the temperature of the heat carrier and a sozo sensor 48 for control of the temperature in the room. The thermal insulation of sections of the CAT 11 is made in such a way that there is a layer 49 between its inner and outer walls, and the internal capacity, which is limited by the inner walls of the thermal insulation, is separated from the outer one by heat-insulating legs 50. On the body of the CAT 11, nozzles 51 are installed to create a layer 49 vacuum. In addition, the induction heater 52 of the wind turbine 53 is placed in the BA 5, to the generator 54 of which it is provided to connect the electrochemical battery 55 chz and the inverter 56, which will allow the wind turbine to be used as an autonomous source of electricity for the drive of the TN 13, which in the usual mode works from network 57.

The heating system of buildings functions as follows.

In the warm period of the year, the energy of the sun from the solar collectors 1 by the circulation pump 3, and the energy of the wind converted by the generator 53 of the wind turbine 52 into electrical energy through the induction heater 51 are transmitted to "40. In BA 5, after which, along the circulation circuit 7 (points A1-A2 Г1-Г2-Г3) heated heat transfer fluid circulating with pump 20 is supplied for charging SAT 11, and the return water is returned to BA 5 for recharging (points

G4-G5-G6-B2-B1) when taps 27, 28, 39-42 are open, and others are closed. The input taps 41, 42 and the output taps 39, 40 can be used to regulate the charging process of individual sections of the SAT 11. During the heating season, there are several options for heat supply to the consumer with such a heat supply scheme (see figure). If the temperature of the coolant in BA 5 is at the level of the technological needs of floor heating (not lower than 35 2C), the coolant is fed from the coolant through the circulation circuit 6 by the circulation pump 18 to HE 9 of the heat consumer 10 and returned to BA 5 for recharging (points A1 -A2-AZ-A4-A5-Ab-BbbB-B5-B41-B3-B2-B1) when taps 21-26 are open, and others are closed. In the event that the temperature of the heat carrier in BA 5 is lower, and in SAT 11 is higher than "35 2С, from the heat supply of the consumer, heat 10 occurs through the circulation circuit 16 (points

G5-G4-A5-Ab-Bb-B5-G3-G2) when taps 37-42 are open, and others are closed. Regulation of heat selection from separate -. sections of SAT 11 occurs by switching taps 39, 42, or 40, 41, depending on the signal from thermosensors 47. If the water temperature in BA 5 is lower than the technological needs of heating, but higher than in

SAT 11, heat supply will take place as follows: through circulation circuit 8 (points

A1-A2-AZ-B1-82-B3-B2-B1) the evaporator 12 TN 13 is loaded and the waste water is returned to

BA 5 with open taps 21, 26, 29-32 with the help of circulation pump 19, and water heated in the condenser 14 TN 13 through the circulation circuit 15 (points B3-А4-А5-АбЕ-Бб-Б5-Б4-Б4) with open taps 23, 24, 35, 36 with circulation pump 18 is supplied to HE 9 and returns back to condenser 14. Other taps in this mode must be closed. In the event that the water temperature in BA 5 will be lower than the water temperature in SAT 11, and the water temperature in both containers will be lower than the technological needs of heating, because heat will be supplied to the heat consumer 10 through the circulation circuit 17 from SAT 11 to the evaporator 12

TN 13 to points G4-G5-G6-B1-82-G1-G2-G3 by pumps 19 or 20 when taps 31-34 and 39-42 are open, and from condenser 14 TN 13, as in the previous version, water by circulation of the circuit 15 when the taps 23, 24, 35, 36 are open, the circulation pump 17 is supplied to the HE 9 and returns back to the condenser 14. Again, the adjustment of the heat extraction from individual sections of the SAT 11 occurs by switching the taps 39, 42, or 65 40, 41, depending on the temperature of the water in the section.

NO 9 of heat consumer 10 is desirable to perform with local floor heating of working areas, as this will allow to equalize the temperature of the heating place along the height, prevent heat loss in areas where there are least people or heavy work is performed, and based on the fact that renewable energy sources have a low density (the optimal temperature of the intermediate coolant is 50-70) their use for

Maintaining a standardized temperature environment is most appropriate in local and floor heating systems, where the temperature on the surface of the plane of contact with the air should not exceed 359C.

During charging and operation of the seasonal thermal energy accumulator 11, in order to reduce energy losses to the ground, air is pumped out of the layer 49 between the inner and outer walls of the SAT 11 through the nozzles 51 and a vacuum is created. ASK 43, with the help of temperature sensors 47 and taps 39-42, regulates the selection of the heat carrier in 70 separate elements of SAT 11, and when the temperature drops to a value close to 409С in one block, the selection is automatically switched to another block with a higher temperature - to prevent icing of the heat-emitting surfaces and pipelines.

When connected to the generator 54 of the wind turbine 53 of the electrochemical battery 55, its outputs can be connected through the inverter 56 to the TN drive 13, as a result of which instead of power from the power grid 75 of the power system 57 we will get an autonomous system of heating and hot water supply based on renewable energy sources. However, in this case, given the additional energy costs for the heat pump drive, it is necessary to increase the unit capacity of the wind turbine and solar collectors.

Claims (3)

The formula of the invention 1. Building heat supply system containing a hot water storage tank, the input of which is connected to solar collectors, a seasonal heat energy storage battery, heat supply circulation circuits, a heat pump, a wind turbine with an electric generator, a system for automatic control of the temperature parameters of the heat carrier in the elements of the heat supply system and temperature control in the room, the consumer of heat, which differs in that it contains the input of the power grid of the power system, connected to the drive of the heat pump, C the electronic heater of the wind turbine, placed in the hot water storage tank, and the heat supply circulation circuits connect the heat energy consumer to the hot water storage tank , a seasonal thermal energy accumulator and a heat pump connected in parallel to each other. co 2. Building heat supply system according to claim 1, which differs in that the seasonal thermal energy accumulator structurally consists of several separate sections filled with water, and in the sections thermal sensors are installed to control the water temperature, and the thermal insulation of each section of the seasonal thermal energy accumulator is made of vacuum layer between the inner and outer walls of the sections. 3. The building heat supply system according to claims 1, 2, which differs in that in order to maintain stable h-indicators of the heat pump power supply voltage with power supply independent of the power grid, an electrochemical battery and an inverter are connected to the generator of the wind turbine. with and? o - o - iii") 60 b5