RU100188U1 - BUILDING HEAT SUPPLY SYSTEM - Google Patents

Abstract

 1. The heat supply system of the building, including the heat node of the building, equipped with a heating device configured to select a coolant with various thermal parameters in the local heating, hot water supply and ventilation circuits, comprising a pump installation, shut-off and control valves and control and measuring equipment, characterized in that at least two dual purpose lithium bromide absorption machines are used as a heating device in parallel made with the possibility of working on the heat pump cycle, while the lithium-bromide absorption machines are included in the hot water supply circuit, in the winter pre-heating circuit of the supply air and air curtain air at the inlets of the building, and in the air conditioning system circuit with a coolant temperature, while for heating and air conditioning of the premises of the shopping center use fan coils located in the inter-ceiling space of each floor, at least two per floor, made with the possibility of cleaning and temperature preparation of the supply air, connected via a heat carrier to absorption bromide-lithium machines according to a two-pipe scheme, while the air ducts of the supply and exhaust ventilation are made of glass magnesium, in addition, the cooling system installed on the roof of the building and hydraulically connected to the absorption are included in the heat supply system of the building lithium bromide machines. ! 2. Heat supply system, characterized in that the hydraulic circuit of the absorption lithium bromide machines is connected to the additional tank

Description

The utility model relates to the field of power engineering and can be used in heat supply and air conditioning systems of buildings and structures, preferably shopping centers.

Heat supply systems of buildings are known, containing local heating systems connected to the supply and return heating mains, a heat source containing a make-up regulator connected to a regulatory body on the make-up piping of the heating system and a pressure sensor installed on the return main of the heating system in the place of connecting the make-up pipeline to the heat source (see Sokolov E.Ya. “Heating and heating networks.” -5th ed. - M.: Energoizdat, 1982, Fig. 5.10, p.149-150).

A disadvantage of the known solutions is the low reliability of the heat supply systems, due to the possibility of emptying the local heating systems at the maximum outflow from the heating network.

A known heat supply system of a building, including heating units of buildings, in which the coolant coming from the direct pipeline of the heating plant, is used in the circuit of the heating devices of the building and then returns from the heating station of the building to the return pipe of the heating plant (RU No. 2148211, MKI F24D 3/12, 2000 g.).

The main disadvantage of such a centralized heat supply system is that the temperature of the heat carrier returning from the building's heat unit to the return main pipe of the heat network is high relative to the ambient temperature, but insufficient for further targeted use of the network heat carrier (SNiP 2.04.05-91 ^∗ Heating, ventilation and conditioning. - M.: Gosstroy of Russia, 1998, pp. 4-10). Such a heat supply system has a low coefficient of efficient use of heat energy of the direct heat carrier and large heat losses to the environment during transportation of the return heat carrier to the centralized heat supply source of the central boiler house or thermal power plant. In the latter version, the system has another drawback - the need for additional, deeper cooling of the return coolant for its further use in the technological cycle of the thermal power plant.

The building’s heat supply system is also known, including the building’s heating unit, equipped with a heating device configured to select a heat carrier with various thermal parameters to local heating, hot water supply and ventilation circuits, containing shut-off and control valves and control and measuring equipment (System of regulatory documents in construction. Code of practice for design and construction. Designing of heating points SP41-101-95. Ministry of Construction of Russia. - M., 1997, p.9 - prototype). Building Norms and Rules SNiP 2.04.07-86 ^∗ , p.23.

The disadvantage of this solution is the insufficient efficiency of heat supply of multi-storey shopping centers (buildings with large height and area of internal premises, with several entrances), which makes it difficult to maintain comfortable temperature conditions in the interior of the building.

The problem to which the claimed utility model is directed is expressed in increasing the heat supply efficiency of buildings of multi-storey shopping centers.

The technical result achieved in solving the problem is expressed in ensuring comfortable temperature conditions in the interior of the building stable in all its rooms, while minimizing operating costs for maintaining the building for heat supply.

The problem is solved in that the heat supply system of the building, including the heating unit of the building, equipped with a heating device configured to select a coolant with various thermal parameters in the local heating, hot water supply and ventilation circuits, containing a pumping unit, shut-off and control valves and control and measuring equipment , characterized in that at least two absorption bromide-l dual-purpose tium machines made with the possibility of working on a heat pump cycle, while lithium absorption bromide machines are included in the hot water supply circuit, in the winter pre-heating circuit for supply air and air curtain air at the building entrances, and in the air conditioning system circuit with temperature coolant, while for heating and air conditioning the premises of the shopping center use fan coil units located in the inter-ceiling space of each floor, at least two per floor, made with the possibility of purification and temperature treatment of the supply air, connected via a coolant to absorption bromide-lithium machines according to a two-pipe scheme, while the air ducts of the supply and exhaust ventilation are made of glass magnesium, in addition, cooling towers installed on the roof of the building are included in the heat supply system of the building and hydraulically associated with lithium bromide absorption machines. In addition, the hydraulic circuit of the absorption lithium bromide machines is connected to the additional feed water tank connected to an external water supply system through a water treatment plant. In addition, the pump installation contains parallel branches, each of which includes a chain containing the first valve in series, a solenoid valve, a pressure gauge, a pump, a U-shaped filter and a second valve, while the pump is detachably included in the chain. In addition, a pressure gauge, a thermometer, a water flow indicator and a gate valve are sequentially installed at the hydraulic inlets and outlets of absorption lithium-bromide machines, while they are detachably connected to the mains mating with them.

A comparative analysis of the features of the claimed solution with the signs of the prototype and analogues indicates the conformity of the claimed solution to the criterion of "novelty."

The combination of features of the utility model provides a solution to the stated technical problem, namely, it provides the opportunity to increase the efficiency of heat supply of buildings of multi-storey shopping centers.

The claimed device is illustrated by drawings, where figure 1 shows a diagram of a heat supply system of a building; figure 2 shows the interpretation of the symbols shown in the diagram; figure 3 is given the specification ABCHN.

The drawing shows the dual-use absorption bromide-lithium machines 1 (ABHM), the hot water supply circuit 2 (with a water temperature of 65/50 ° C, hereinafter, the water temperature on the discharge branch, i.e. 65 ° C, is indicated first, and below the line given the water temperature on the return branch (i.e. 50 ° C), circuit 3 of the winter pre-heating of the supply air and air curtain air at the entrances of the building (with a water temperature of 95/70 ° C), the air conditioning system circuit 4 with a coolant temperature of 65/50 ° C or 5/11 ° C. In addition, fan coil units 5, air ducts 6, cooling towers 7, additional feed water tank 8 connected to an external water supply system 9 are shown through a water treatment plant 10, a pump installation 11 containing parallel branches 12, a first valve 13, an electromagnetic valve 14, a pressure gauge 15 , pump 16, U-shaped filter 17 and the second valve 18. In addition, ABHM control and measuring equipment is shown: pressure gauge 19, thermometer 20, water flow indicator 21 and gate valve 22.

ABHM 1 operate on a heat pump cycle when using the heat of combustion of natural gas. The hot water supply circuit 2 provides year-round hot water supply to sanitary consumers. The circuit 3 of the winter pre-heating of the supply air and air curtain air at the inlets of the building with a coolant temperature of 95/70 ° C is intended for pre-heating the air of the supply systems and air curtains in winter. The air conditioning system circuit 4 with a coolant temperature of 65/50 ° C (5/11 ° C) is used to properly prepare (heat or cool) the air used in the air conditioning system.

Fancoils 5 (also called fan coil units) are units including: a fan, a heat exchanger, an air purification filter and a control panel (in fact, this unit is similar in structure, design and purpose to the indoor unit of an air conditioner (split system). air, or a mixture of primary and recirculated air, depending on the period of the year, is cooled or heated in the heat exchanger Cold water is supplied to the fan coil pipelines in the warm period of the year or hot water is cold periods of the year, that is, fan coils operate in cooling mode during the warm period and heating during the cold season. The number of fan coils operating in the central air conditioning system of the building is limited only by the capacity of the chiller. Like split systems, fan coils can be wall, floor, ceiling , cassette, channel and other types.

Air ducts 6 of supply and exhaust ventilation are made of modern non-combustible material - glass-magnesium. This material is not harmful to human health, does not require additional thermal insulation, a smooth surface prevents the formation of noise, does not corrode. Assembly technology allows you to collect (glue) ducts in place of sheets. The service life is more than 20 years, which significantly exceeds the shelf life of galvanized iron ducts. The use of such material for the manufacture of ducts allows you to abandon the use of steel, which will significantly reduce the bearing load on the building structure.

Cooling towers 7 are made as recuperative type closed fan heat and mass transfer apparatuses in which cooled water is supplied to a heat exchanger, the outer surface of which is blown by an air stream and irrigated with circulating water. They are not structurally different from the known devices of similar purpose and performance and are intended for cooling water circulating in the air conditioning system 4 (in summer). They are mounted on the roof of the building, protecting from heating by solar heat and from rain.

Pumps 16 are not structurally different from the known ones used for similar purposes, except for the pumps used to supply feed water, for which it is advisable to use variable frequency pumps (these pumps are not shown in the drawings).

Shutoff valves and instrumentation in design correspond to known devices of similar purpose and performance.

The claimed heating system operates as follows.

The operation of absorption chillers is based on the use of a binary solution, i.e. a mixture of two liquids with a sharply different boiling point, while a liquid with a lower boiling point (water) is a refrigerant, and a liquid with a higher boiling point (aqueous solution of lithium bromide) is an absorbent (absorber). This absorbent is capable of absorbing refrigerant vapors in large quantities in a short period of time, in addition, when used in air conditioning systems, it is more harmless in comparison with ammonia (used in water-ammonia absorption refrigeration machines). At the same time, chillers of this type have a number of advantages, which include compactness, harmlessness, safety (due to low pressure in the system), lack of vibration, which allows them to be installed in the upper floors of buildings, as well as reliability.

In the heat exchange unit (not shown in the drawings), an aqueous solution of lithium bromide is evaporated due to the heat of the combusted gas. Because the boiling point of water is much lower than the boiling point of lithium bromide; when heated, almost pure water vapor is released from the solution. From this unit, water vapor enters the condenser (not shown in the drawings), where it is compressed, giving off the condensation heat to the water circulating in the heating system. The condensate is discharged into the ABXM evaporator (not shown in the drawings), which also receives the heated water from the fan coil 5 irrigation chamber, where it is sprayed with a special device. The ABXM evaporator (not shown in the drawings) is connected to the ABXM absorber (not shown in the drawings), in which there is a solution of lithium bromide. Due to the fact that lithium bromide intensively absorbs water vapor, the process of evaporation of water occurs in the evaporator, and due to this, its cooling. Cold water pumping unit 11 is fed to the nozzles of the irrigation chamber of the fan coil 5 for cooling the air. The heat generated in the absorber due to the absorption of water vapor by a solution of lithium bromide is removed by supply water from the cooling tower 7.

In ABXM devices, processes proceed under vacuum, so they must be completely tight. The vacuum in the apparatus is maintained by vacuum pumps (not shown in the drawings), sucking air from the absorber and evaporator.

Fancoils 5 provide for the selection of heat (or cold) from the water entering them from ABHM 1 by blowing their heat-exchange blocks. In addition, air purification is provided.

Thus prepared air (heated or cooled, depending on the season), enters through ducts 6 to the zones of its distribution in the premises of the center. Thus, the maintenance of the required parameters and air quality in maintained premises or technological volumes of the shopping center building is ensured.

The selection of hot water to the hot water supply circuit 2 and the winter pre-heating circuit 3 of the supply air and air curtain air at the inlets of the building is carried out from the ABHM, according to a scheme similar to that described for the air conditioning system 4, they are similar and differ only in the thermal parameters of the supplied hot water.

When heating the shopping center in the cold season, the cost of gas and electricity for ABHM is about 2 million rubles. When using heat from the city heating main, the costs will be about 37 million rubles. When using chillers, the costs will be about 3 million rubles.

When cooling the air in a shopping center in the warm season, the cost of gas and electricity for the ABHM is about 379 thousand rubles. When using chillers, the costs will be about 862 thousand rubles.

In addition, the application of the claimed heat supply system allows you to flexibly control the system both centrally (by changing the temperature of the water in the air conditioning circuit ABHM) and locally (by changing the performance of the fan coil), depending on the need.

Claims (4)

1. The heat supply system of the building, including the heat node of the building, equipped with a heating device configured to select a coolant with various thermal parameters in the local heating, hot water supply and ventilation circuits, comprising a pump installation, shut-off and control valves and control and measuring equipment, characterized in that at least two dual purpose lithium bromide absorption machines are used as a heating device in parallel made with the possibility of working on the heat pump cycle, while the lithium-bromide absorption machines are included in the hot water supply circuit, in the winter pre-heating circuit of the supply air and air curtain air at the inlets of the building, and in the air conditioning system circuit with a coolant temperature, while for heating and air conditioning of the premises of the shopping center use fan coils located in the inter-ceiling space of each floor, at least two per floor, made with the possibility of cleaning and temperature preparation of the supply air, connected via a heat carrier to absorption bromide-lithium machines according to a two-pipe scheme, while the air ducts of the supply and exhaust ventilation are made of glass magnesium, in addition, the cooling system installed on the roof of the building and hydraulically connected to the absorption are included in the heat supply system of the building lithium bromide machines. 2. Heat supply system, characterized in that the hydraulic circuit of the absorption lithium bromide machines is connected to an additional feed water tank connected to an external water supply system through a water treatment unit. 3. A heat supply system, characterized in that the pump installation contains parallel branches, each of which includes a chain containing sequentially installed first valve, an electromagnetic valve, a pressure gauge, a pump, a U-shaped filter and a second valve, while the pump is detachably included in the named chain . 4. Heat supply system, characterized in that a pressure gauge, a thermometer, a water flow indicator and a valve are installed in series on the hydraulic inputs and outputs of the lithium-bromide absorption machines, while they are detachably connected to the mains interfaced with them.