EA036357B1 - Solar centralized heating system based on thermal batteries - Google Patents

Abstract

The invention relates to the renewable energy sector, in particular, to thermal systems of civil and industrial buildings, where heat supply (hot water supply and heating) can be used. The objective of the invention is to develop a system for seasonal storage of solar thermal energy in large volumes, solving a problem of energetically and environmentally efficient heat supply (hot water supply and heating) for residential communities and multi-storeyed houses. The technical result which can be achieved by implementing the claimed invention is an increase in the seasonal mean solar energy utilization factor, which makes it possible to supply 70-90% of the required thermal energy for heating and hot water supply due to the solar energy. Moreover, the problems related to daily and seasonal variations of intensity of the solar thermal energy will be solved, which allows for the system functioning as a centralized heat supply system all year round, regardless of the weather. Another achievable technical result of the invented system is its environmental friendliness due to the use of solar energy, and its scalability, i.e. capability to integrate other adjacent buildings and districts to a centralized heating system based on the solar thermal energy seasonal accumulation technology. The technical result is achieved thanks to the fact that the solar thermal energy seasonal accumulation technology provides a network of solar collectors represented as a group of subgroups interconnected in parallel. Each subgroup comprises solar collectors interconnected in series. Their number varies from two and over, depending on the required resulting temperature of the heat transfer medium. Thermal batteries based on materials for high density energy storage (MKhE-VP1 and MKhE-VP2) are used as short-term batteries. For the case when the system cannot adequately cover the loads for heating and hot water supply, an additional boiler is installed between the consumer unit and the heat exchanger. The system further comprises a smart control unit having an access to temperature sensors, water level detectors, flowmeters, shut-off valves and pumps.

Description

The invention relates to the field of renewable energy, namely to thermal systems of civil and industrial buildings, where heat supply (hot water supply and heating) can be applied.

There is a known system that combines the thermal energy of the soil with the waste heat of the ventilation system and the sewage drain of the building (patent RU 2364795 C2, IPC F24D 9/00, published on 20.08.2009). Recirculation of the collected energy is provided by heat pump equipment for hot water supply and heating of buildings; the heat pump allows the system to be used to cool the premises in summer. Excess heat energy is accumulated in the ground heat storage and / or heat storage.

The disadvantage of such a system is the low specific heat content of the heat energy from ventilation emissions, as well as the complexity of the design and the use of several heat pumps, which leads to an increase in the cost of the system.

Known heat pump system for heating air in buildings (patent KZ, A4 30153 F24J 2/04, published on July 15, 2015), designed for autonomous heat supply. Such a system is implemented for a single building by adding an additional room for preheating the outside air and a ditch for heat storage. The operation of the thermal installation is ensured through the use of the following devices: heating devices and pumps for the circulation of the coolant, solar collectors, a heat pump, radiators, floor heating.

The disadvantage of such a system is the complexity of the structure, which leads to its economic inefficiency for a single building.

The closest analogs of the invention are a heat pump system for heating residential buildings, which includes an air-to-water heat pump unit with built-in mandatory elements: a compressor performing two-stage compression, an evaporator, a throttling element, a condenser, an intercooler, and a simplified modified scheme for collecting low-grade heat for a heat pump installations in the form of removed exhaust air from the premises, and the exhaust grilles are connected to the vertical collection channel, and a fan is connected in series to the exhaust shaft, which transfers warm exhaust air to the evaporator (KZ patent, A4 28844 F24D 3/02, F24D 3/14, published 08/15/2014). This device collects low-grade heat from the waste air through the building ventilation systems and converts it into high-potential heat. The resulting energy is accumulated in the form of hot water and transferred to the building's heating system. That is, the medium for storing energy is water. The efficiency of the device is provided by a heat pump installation.

The disadvantages of this analogue are that the system cannot be used as a centralized heat supply system and does not provide for long-term storage of excess heat and is intended for one house / building. Moreover, the exhaust air through the ventilation system has a specific heat content significantly lower than that of solar energy.

The objective of the invention is to develop a system for seasonal storage of solar thermal energy in large volumes, decisive energy and environmentally efficient heat supply (hot water supply and heating) of residential neighborhoods and multi-storey buildings.

The technical result that can be achieved with the implementation of the claimed invention is to increase the coefficient of the average seasonal use of solar energy, which makes it possible to supply 70-90% of the required thermal energy for heating and hot water supply due to solar energy. In addition, the problems associated with daily and seasonal fluctuations in the intensity of solar thermal energy will be solved, which allows the system to function as a centralized heating system all year round regardless of the weather. Another achievable technical result of the claimed system is its environmental friendliness through the use of solar energy and scalability, that is, the ability to integrate other nearby buildings and neighborhoods to a centralized heating network based on the technology of seasonal accumulation of solar thermal energy.

The technical result is achieved due to the fact that the technology of seasonal accumulation of solar thermal energy contains a network of solar collectors (with built-in expansion valve, evaporator, compressor, condenser), which is a group of parallel connected subgroups. Each subgroup is series-connected solar collectors, the number of which varies from two or more, depending on the required resulting temperature of the coolant. The solar collector network is connected to the short-term accumulator system via a heat exchanger. Using a heat exchanger makes it easy to switch to other low-grade heat sources.

Heat accumulators based on high-density energy storage materials МХЭ-ВП1 and МХЭ-ВП2 are used as short-term batteries. The system also contains a ground heat storage, which is a network of borehole heat exchangers. The ground heat storage and user unit are connected to the short-term accumulators through a heat exchanger. The circulation of the coolant between the ground heat storage and the heat exchanger is carried out by a pump. For the case when the system does not sufficiently cover the heating loads and

DHW, an additional boiler is installed between the user block and the heat exchanger. And also the technical result is achieved due to the fact that the system collects data from temperature sensors, water level, pressure, flow meters and sends them to an intelligent control unit, where the received signals are processed and commands are given to control valves and pumps.

Description of the device in a static state.

The design of the device is shown in the drawing. The solar centralized heating system contains a network of 1 solar collectors (with built-in expansion valve, evaporator, compressor, condenser), connected to a short-term accumulator system through a heat exchanger 4. The solar collector network is a group of parallel connected subgroups, where each subgroup is series-connected solar collectors , the number of which may vary depending on the required resulting temperature of the coolant. Heat accumulators based on materials for high-density energy storage 2 - МХЭ-ВП1 and 3 - МХЭ-ВП2 are used as short-term batteries. These batteries allow you to store more heat than water batteries. МХЭ-ВП1 and МХЭ-ВП2 differ in heat capacities, the heat capacity of МХЭ-ВП1 is higher than that of МХЭ-ВП2. The system contains a ground heat accumulator 5, which is a network of 6 borehole heat exchangers. The heat pump 7 is connected between short-term accumulators and a ground heat accumulator. The circulation of the heat carrier between the ground heat accumulator and the heat pump is carried out by the circulation pump 11. The user unit 8 is connected to short-term accumulators through the heat exchanger 9. An additional boiler 10 is installed between the user unit and the heat exchanger for the case when the system does not sufficiently cover the heat loads of heating and hot water supply.

The system additionally contains an intelligent control unit 12, where data is collected from sensors of temperature, water level, pressure, flow meters, after processing of which the shut-off valves and pumps are controlled. Depending on the incoming signals from the sensors, it is possible to remotely open or close valves, control the flow of heat carriers in heat exchangers, turn on or off solar collectors, pumps, or change the direction of flow in pipes.

Description of the device in operation.

Summer mode: in the warm season, heat is collected by system 1 of solar collectors and accumulates in short-term batteries, thereby charging them. Hot water supply in summer is provided directly from short-term accumulators, where the liquid is heated to 80-100 ° C. In case of a shortage of stored energy in short-term batteries to meet consumer demand for hot water due to insufficient intensity of solar radiation, the water is heated by an additional boiler / heater to the required temperature. Excess thermal energy of short-term accumulators with the help of a network of borehole heat exchangers is directed to charging the ground heat accumulator. The ground heat accumulator has a cylindrical shape and is thermally insulated on the ground surface. The downhole heat exchangers are connected to each other so that the heated liquid from the short-term accumulators heats up the soil from the center to the edges of the system, after which it is fed back to the short-term accumulators. Consequently, the core temperature of the soil heat storage is the highest.

Winter mode: in winter, during the heating season, heat is extracted from the geothermal accumulator with the help of borehole heat exchangers, while the heat carrier is taken from the edge to the center of the ground accumulator. Thermal energy will also come from solar collectors. Thus, the temperature in short-term batteries will be maintained at 65-90 ° C, which is sufficient for heating and hot water supply (DHW) of modern buildings.

Claims (2)

CLAIM 1. Solar centralized heating system based on heat accumulators, including circulation pumps, heat exchangers and valves, characterized in that it additionally contains a network of solar collectors, short-term accumulators, ground heat accumulator, an additional boiler for water heating, an intelligent control unit, and as short-term accumulators installed heat accumulators based on materials for storing high density energy MHE-VP1 and MHE-VP2, and the ground heat accumulator is a network of borehole heat exchangers connected in series from the center to the edges. 2. The solar centralized heating system according to claim 1, characterized in that the solar collector system is a group of parallel connected subgroups, each subgroup being at least two solar collectors connected in series.