LT6009B - Heating system - Google Patents

Abstract

Invention relates to the field of thermal technology and can be used as a heat supply of buildings connected to the district heating system in the system of trunk pipelines system. The proposed technical solution is a centralized heating system with the use of solar equipment or other self-contained heat generator so that under certain conditions (both summer and winter) in an autonomous heat generator heat generated excess energy is transferred to the trunk of centralized heat supply system networks. This inventive adaptation in individual cases is to give autonomous generator heat generated excess heat transfer to other thermal power users, reducing heat loss and maintain a certain temperature level regardless of their length and distance from the central heat production site to the consumer. Under the proposed invention new is that at the beginning of solar collectors to generate heat energy surplus equipment is protected from overheating, while the user can supply heat to the district heating network.

Description

The invention relates to the field of thermal engineering and can be used as a system for supplying heat from buildings connected to a district heating system to the main pipelines of that system.

State of the art

District heating is a complex system of heat transfer and distribution between producers and consumers. Currently, not all of the features of this system that can be used during their operation and operation are utilized.

The solar system, like other autonomous heat generators, can be used (combined) with a centralized heating system. Solar collector is a device used to collect solar energy and transfer heat to the water and space heating system. The efficiency of solar collectors can vary significantly at different times of the year, due to differences in the amount of solar energy collected and the temperature of the air. In order to select the sufficient power of this autonomous heat generator, it is necessary to evaluate the possible maximum heat demand for the premises. Let's assume this is 100% during winter. In order to meet 100% of the heat demand, the capacity of the solar system must be calculated so that it can generate and deliver the required amount of heat, even at low air temperatures, high clouds and high hot water consumption.

This way, estimating the heat demand and installing the equipment accordingly during certain periods of high air temperatures and sunny weather in the summer would result in significant excess heat (up to 95% of the heat demand). In this case, a significant problem would be where to give away or utilize the excess heat generated by the solar panels. In the event of overheating, the equipment will gesture, reduce overall life and reduce reliability.

Currently, there are no simple reliable technical solutions that can provide reliable control and regulation of heat generation. This problem is solved by reducing the total installed solar capacity, although this equipment has the technical capability to generate significantly higher heat output. Costly blinds are also used to reduce the intensity of sunlight. In this case, the generation of thermal energy is significantly limited, which in turn significantly extends the payback period of the installed equipment and reduces its profitability.

In Lithuanian patent no. 5778 describes the combined use of two heat sources in district heating and hot water supply systems. In this case, the heat would be alternately discharged into the building from a working district heating system and from a heat pump or other autonomous heat generator producing heat from a renewable natural heat source.

Pat. The technical solution described in 5778 cannot be used as efficiently as possible due to the limited heat demand of the individual user or group of users. When it is possible to generate excess heat with an autonomous heat generator, it is not possible to transfer it to downstream users of the district heating system or simply to the main pipelines, in some cases in order to maintain their higher temperature and thereby reduce losses of district heating or returning heat.

The essence of the invention

The proposed technical solution is to use a district heating system in combination with solar panels or other autonomous heat generators so that, under certain weather conditions (both summer and winter), the excess heat generated by this autonomous heat generator is transferred to the district heating system piping. According to the present invention, the novelty of the invention is that when the solar collectors generate excess heat energy, the equipment is protected from overheating and, at the same time, the user can supply the heat himself to the district heating networks. The present invention further explores an embodiment wherein the autonomous heat generator is a solar collector. However, other equipment using renewable energy sources (eg geothermal, air-to-water heat pumps, etc.) may be used to generate heat and similarly transfer excess heat to central heating systems.

According to the invention, in a heating system comprising mains heat supply networks, heating unit piping and equipment, as well as building hot water supply and building heating systems and utilizing an autonomous heat generator, the autonomous heat generator, more particularly a solar collector, forms an independent module which through a three-way valve The heat exchanger and the circulation pump are connected to the main heat supply network. The system also incorporates a heat meter returning from the consumer and a three-way valve control to regulate the flow of heat energy. The heat carrier temperature determines the excess heat generated by the autonomous heat generator, and when this temperature reaches a predetermined value, the three-way valve is set to transfer the excess heat to the main heat supply network. There are three types of connection of the stand-alone heat generator to the main heat supply network: 1) when the excess heat transfer pipeline is connected to the heat transfer pipeline supplied to the customers of the main heat supply network, and the stand-alone heat generator return pipeline; 2) when the excess heat and autonomous heat generator is connected to the backbone of the main heat supply network; and 3) when the excess heat and autonomous heat generator is connected to the heat carrier pipeline supplied to the customers of the main heat supply network.

In addition, the system may be equipped with a heat meter to record the energy delivered to the main district heating network.

Adapting this solution would significantly reduce the cost of heat and hot water, and the return on investment. Consumers connected to district heating systems would have the option of partially abandoning the burning of fossil fuels and switching to renewable sources of energy in favorable climatic conditions. Consumers of such autonomous heat generators, which can always meet 100% of their heat demand, would not only be able to buy heat from central heating networks, but would also be able to sell surplus, which would accordingly have to cover the marginal running costs of the equipment. For solar panels, this would be the cost of electricity, circulation pumps and automation, equipment depreciation. In some cases, users of such automatic heat generators would receive heat for their own needs free of charge, or even make a profit from selling its surplus. It is at this expense that the return on investment is reduced to a minimum. It is not necessary for the building to be connected to a central heat supply system to enable such a solution. Profitability would remain even if the heat networks were close to the building.

Also, the transfer of excess heat energy would allow for a better balancing of heat quantities in district heating systems by raising the temperature of the pipelines in areas where the heat carrier temperature is lower. Measures are taken to improve the insulation of the pipelines to reduce heat loss on district heating lines. However, in some cases, another way to reduce heat loss is to reduce the distance between the points where the heat is produced and consumed (producers and consumers). This solution can be implemented by connecting the maximum number of heat producers to the district heating systems. In order to reduce the distance between producers and consumers, and to reduce heat losses in the main pipelines, existing district heating schemes require the construction of additional boiler houses and heat stations. However, such a way (to build new boiler plants and heat plants near or near the user) is economically and environmentally unjustifiable (large investments in construction and equipment, the environment and nature are contaminated with waste heat).

Therefore, a radically new district heating system scheme is proposed that can be easily integrated into existing district heating system and heat production schemes. Under the proposed scheme, a thermal user (a building or structure connected to a district heating system and equipped with a heating point to regulate the amount of heat energy) could easily protect their solar thermal equipment from overheating with a dual function of producing and supplying heat not only for itself, but also for a district heating system. Using an autonomous heat generator with this function, excess heat produced would be transferred to the main pipelines of the district heating system, thus supplementing the heat energy. In some cases, this would transfer excess heat to the closest heat consumers or maintain the optimum temperature for the functioning of the existing central heating system.

This scheme would eventually reduce the heat losses in the pipelines in individual cases and maintain a certain temperature level regardless of their length and distance from the central point of heat production to the customer. It would also reduce the amount of pollution generated by the production of thermal energy through the use of environmentally friendly stand-alone heat generators using renewable energy sources. And, of course, solving the problem of possible overheating of solar panels to meet maximum heat demand would be effectively solved.

Brief description of the drawings

The invention is explained in the drawings, which show a scheme of connecting a solar collector system or other autonomous heat generator to a district heating system of a building and transferring the generated heat energy to the main pipelines. FIG. 1 - connecting the solar system to the systems where the excess heat generated is fed to the main heat supply pipeline and the heat is taken from the return pipeline; FIG. 2 - connecting the solar system to the systems where the excess heat generated is fed to the main heat return pipeline and the heat is taken from the return pipeline accordingly; FIG. 3 - connecting the solar system to the systems where the excess heat generated is fed into the main heat supply pipeline and the heat is taken from the supply pipeline accordingly.

Description of Implementation of the Invention

The present invention describes a standard circuit diagram of a district heating system to which a solar system is additionally connected. The following elements are indicated and marked in the diagram: main heat supply networks 1; heat unit piping and equipment - 2; building hot water supply system - 3; cold water for hot water preparation - 4; heat substation facilities in the building

- 5; building heating system - 6; heat exchanger - 7; solar system or other autonomous heat generator - 8; 3-way valve - 9; heat exchanger - 10; circulation pump - 11; heat energy meter - 12; heat exchanger - 13. Shutoff valves, counters, thermometers and other elements are also shown in the diagram. The flow directions and uses of the heat medium are indicated respectively: T1 - heat carrier (water and similar) supplied from heat supply networks; T2 - heat carrier (water and similar) returning to heat supply networks; T3 - water supplied to the consumer's hot water system; T4 - water returning from the consumer hot water system; T5 - heat medium supplied to the consumer heating system (water and the like); T6 - heat carrier returning from the consumer heating system (water and similar); T7 - heat medium supplied to consumers (water, etc.); T8 - heat carrier returning from heat supply networks (water and similar).

The heat transfer medium T5 from the solar system 8 enters the central heating system of the building through a heat exchanger 13. The solar circuit is filled with antifreeze. The central heating circuit of the building is filled with heat energy carrier - water. The cooled heat carrier T6 returns through the pipeline to the solar system. In the event that excess thermal energy is generated, the temperature of the heat carrier T6 increases in the pipeline. When the temperature reaches the set value, the three-way valve 9 directs the heat energy flow to the heat exchanger 10, activates the circulation pump 11 and directs the excess heat energy to the main district heating networks 1. The heat meter 12 records the amount of heat supplied to the main networks 1.

FIG. Figure 1 shows the supply of excess heat energy to the main heat supply pipeline and the heat recovery from the return pipeline. Feeding and picking in the scheme of FIG. 2 - to and from the return pipe, respectively. Feeding and picking in the scheme of FIG. 3 to the feed line and from the feed line, respectively. The choice depends on the temperature regime of the specific district heating system. Even if the building is not connected to the central heat supply system, it would be wise to connect the autonomous heat generator installed in it to the nearby main heat supply pipelines.

The total amount of heat delivered by autonomous heat generators to specific district heating networks may be limited by the minimum hot water requirement during the summer. But even if central heating systems have nowhere to supply excess heat in the summer, this issue could be dealt with centrally (eg transfer of excess heat to the river, conversion of heat to electricity, etc.).

Claims (7)

DEFINITION OF INVENTION 1. A heating system comprising mains heat supply networks, heating unit piping and equipment, as well as building hot water supply and building heating systems, and utilizing an autonomous heat generator, characterized in that the autonomous heat generator forms an independent module which through a three-way valve (9). ), the heat exchanger (10) and the circulation pump (11) are connected to the main heat supply network (1). 2. A heating system according to claim 1, characterized in that the autonomous heat generator comprises a solar collector (8). 3. A heating system according to claim 1 or 2, characterized in that the system comprises a temperature sensor for returning heat transfer medium (T6) and controlling a three-way valve (9) for regulating heat flow, where the temperature of the heat transfer medium (T6) is determined by an autonomous heat generator the three-way valve (9) is set for transferring the excess heat to the main heat supply network (1). 4. A heating system according to any one of the preceding claims, characterized in that the heat transfer pipeline of the autonomous heat generator is connected to the heat transfer pipeline supplied to the customers of the main heat supply network (1) and the return heat pipe of the autonomous heat generator to the main heat supply network. ) return pipeline. 5. A heating system as claimed in any of claims 1 to 3, characterized in that the heat transfer pipeline and the return pipeline of the autonomous heat generator are connected to the return pipeline of the main heat supply network (1). 6. A heating system as claimed in any one of claims 1 to 3, characterized in that the heat transfer pipeline and the return pipeline of the autonomous heat generator are connected to the heat transfer pipeline supplied to the customers of the main heat supply network (1). 7. A heating system as claimed in any one of the preceding claims, characterized in that the system includes a heat energy meter (12) for recording the energy delivered to the main district heating network (1).