RU2780725C2 - Apparatus for heat insulation of buildings and structures - Google Patents

Abstract

FIELD: building.

SUBSTANCE: invention relates to the field of building, in particular, to an apparatus for heat insulation of buildings and structures and can be used in new and reconstructed buildings in the Arctic, Antarctica, the Far North, and the Far East, in areas with permafrost soils and low outside air temperatures. Apparatus for heat insulation of buildings and structures comprises a heat insulation layer and an evaporation unit. The condensing unit is placed in a heated room equipped with a heating system. The evaporation unit is made in the form of flat ribbed tubular or plate-type heat exchangers, is equipped with a refrigerant boiling pressure adjuster, is installed outside of the heat insulation layer of the building, and is connected to the condensing unit of the refrigeration set. The boiling pressure adjuster is set to the boiling point of the refrigerant equal to or lower than the outside air temperature by 5 to 10°C.

EFFECT: reduced heat losses through the enclosing structures of the building, reduced power consumption for heating with a reduction in the harmful environmental emissions.

3 cl, 2 ex, 1 dwg

Description

The invention relates to the field of construction, in particular, to the construction of passive buildings and can be used for the construction of new and reconstructed buildings and structures.

The priority areas for the application of the invention are public, industrial and administrative premises of buildings and structures of enterprises of various ministries and departments located in the regions of the Arctic, in the regions of the Far North and the Far East, in areas with permafrost soils and low outdoor temperatures.

Widely known are traditional devices for thermal insulation of residential, public, administrative and industrial buildings and structures, used in accordance with current legislative documents, including the Code of Rules SP 60.13330.2012 "SNiP 41-01-2003. Heating, ventilation and air conditioning air" (approved by order of the Ministry of Regional Development of the Russian Federation of June 30, 2012 N 279).

The traditional use of heat and vapor barrier materials is also regulated by current legislative documents, including SNiP 23-02-2003 "Thermal protection of buildings", as well as SP 293.1325800.2017 Code of Rules "Facade heat-insulating composite systems with external plaster layers".

The disadvantage of the traditional method of thermal insulation of buildings and structures is the fundamental impossibility to completely eliminate heat loss through the building envelope, which leads to a large consumption of energy resources for heating with a simultaneous release of thermal energy into the environment.

So, for example, for new and reconstructed buildings (public, administrative and industrial) of the highest energy efficiency class "A" with the most significant degree-day of the heating period equal to 12000, the normalized value of the heat transfer resistance of enclosing structures is: R _reg \u003d 6, 4 m ₂ ⋅ ° С / W and, therefore, for buildings located in the climatic sub-regions of Russia 1V, 1G, 1D, IIA, IIB, IIB, IIG, IIIA and IIIG with an average monthly temperature in January up to minus 28-32 ° С, normalized specific heat losses from each square meter of a heat-protective fence can reach significant values:

where

q - specific heat loss, W / m ² ,

R _reg - normalized value of resistance to heat transfer of enclosing structures, m ² ⋅ ° С / W,

tvn - temperature of internal air, °С,

tout - outdoor air temperature, °С.

It is known from the prior art that a building heating and air conditioning system is constructed by using heat sources and heat pumps containing indoor and outdoor units, according to which the outdoor units of air conditioners are placed in rooms heated by heat sources, which creates the possibility of heat recovery and reduced energy consumption (patent No. RU 2725127C1 , IPC F24D 3/18 F24F 1/00 F24F 7/00).

The disadvantage of this method is significant heat loss through the building envelope.

From the prior art is also known a method of erection and arrangement of the outer walls of a building, patent RU 2042775 C1 IPC E04H 1/00, E04B 1/35 (US Patent N 4433720, class 52-169.11), according to which steel vertical plates are used in the outer walls, buried in the ground and transferring heat from the zone of a constant heat source in the ground into the wall, and the steel plates outside the ground are insulated with heat-insulating material from the inside and outside. Due to heat gains from a constant heat source in the ground, vertical steel plates have a higher surface temperature in winter than the ambient temperature, as a result of which the temperature difference on the inner layer of thermal insulation decreases and the heat losses of the building are reduced. This invention, in terms of the totality of features, is a prototype of the claimed device for thermal insulation of buildings and structures.

The disadvantages of the prototype is the warming of the soil in the summer and, as a result, the inability to use in permafrost areas.

The technical task of the proposed device is to eliminate these shortcomings.

The technical result of the proposed device is to reduce heat loss through the building envelope, reduce energy consumption for heating while reducing harmful emissions into the environment (thermal energy, carbon dioxide, nitrogen oxides).

The solution of the set technical problem and the achievement of the desired result are ensured by the fact that in the claimed device for thermal insulation of buildings and structures, containing heat-insulating building materials and a refrigeration unit with a compressor and condenser unit and an evaporator unit, the compressor and condenser unit is located in a heated room equipped with a heating system , and the evaporator unit is made in the form of flat finned tubular or sheet-pipe evaporators, equipped with a refrigerant boiling pressure regulator, installed outside the heat-insulating layer of the building enclosure, connected to the compressor and condenser unit, and the evaporating pressure regulator is set to the refrigerant boiling temperature close to the outside air temperature. At the same time, the heated room is equipped with an automatic air temperature control system by changing the heat output of the heating system, which can be equipped with an air or water circuit for transferring the body to the heated room, contain boilers for hydrocarbon fuels, water or electric air heaters, and the heated room may contain outdoor units. air conditioning systems.

The technical result of the invention is to create a device for thermal insulation of buildings and structures, providing a significant reduction in energy consumption by returning a part of the heat loss inside the building, equal to the cooling capacity of the refrigeration unit.

The reason for the expediency of using the proposed device for thermal insulation of buildings and structures is the need to reduce the consumption of energy resources for heating buildings and structures while reducing the environmental burden on the environment in the form of emissions of thermal energy and harmful substances in accordance with the State Policy of the Russian Federation in the Arctic for the period up to 2035 .

The advantages of the claimed device for thermal insulation of buildings and structures are:

- reduction of heat losses of buildings and structures through heat-protective fences,

- reducing the cost of energy resources for heating buildings and structures,

- reduction of ecological load on the environment,

- the ability to make the structure invisible to night vision devices, which in the conditions of the polar night can be used to mask objects,

- the possibility of embedding the proposed thermal insulation device in the heating and air conditioning systems of a building or structure,

- the possibility of recuperation of heat losses of buildings and structures through fences.

The essence of the invention is illustrated in the figure. The figure shows a diagram of the claimed building thermal insulation device. The figure shows:

heated room of the building 1, condensing unit 2, load-bearing external wall of the building 3, adhesive layer 4, thermal insulation layer 5, plaster layer 6, evaporator block 7, decorative facade cladding panels 8, copper heat distribution panel of the evaporator block 9, collectors 10, copper pipes 11, expansion valve 12 installed on the liquid line of the refrigerant pipes 13, evaporating pressure regulator 14 installed on the steam line of the refrigerant pipes, fittings 15 for connecting adjacent evaporator units, the direction of the hot air flow from the condensing unit is shown in footnote 16.

The device works as follows.

During the heating season (cold period of the year), the compressor-condensing unit 2 is switched on, connected by two refrigerant pipes 13 to the collectors 10 of the evaporator unit 7, and they are maintained in them using an automatically operating boiling pressure regulator 14, the boiling point of the refrigerant, equal to or close to the outdoor temperature .

When the air temperature inside the building is +20°C and the outside air temperature, for example, minus 20°C, the heat flow through load-bearing walls 3, adhesive composition 4, thermal insulation layer 5 and plaster layer 6 is proportional to the wall area, heat transfer coefficient and temperature difference, in in this example equal to 40°C.

All the heat of this heat flow is transferred in the process of heat transfer to the evaporator unit 7 and is spent on boiling the refrigerant, the vapor of which then carries away the absorbed energy to the compressor and condenser unit 2, and then the heat is transferred (footnote 16) to the internal air of the heated room 1. Thus, the heat of the internal air that has escaped through the wall of the building is intercepted by the evaporation unit 7 and returned inside the heated room 1, thereby reducing the heat load on the heating system. At the same time, the outer surface of the building wall, consisting of cladding panels 8, has equal temperatures on the inside and outside (minus 20°C), and for this reason, the heat flow from the building to the outside through the surfaces covered by the evaporation unit 7 is equal to zero ( !).

Example 1

In this example, the thickness of the heat-insulating layer 5 (expanded polystyrene) is determined in accordance with SNiP 23-02-2003 "Thermal protection of buildings", and the value of the heat transfer resistance of enclosing structures is: R _reg =6.4 m ² ⋅°C / W. As the compressor and condenser unit 2 of the refrigeration unit, the FG / FS-665 SZ unit of domestic production was selected, the cooling capacity is 16 kW, the boiling point is up to - 40 ° С. Let's assume that in the immediate vicinity of a building or structure, temperature sensors record a negative outdoor temperature of minus 20°C, while the internal air temperature is plus 20°C.

In this case, the regulator maintains the boiling point of the refrigerant in the evaporators at minus 20°C. At the same time, the heat flow through the thermal insulation of the building complies with the regulatory requirements, but all heat losses are transferred to the evaporator unit 7 and then, with refrigerant vapor, are returned inside the building to the heated room 1 through the compressor and condenser unit, which reduces the load on the heating system. It is important that in this example the temperature of the outside air and the temperature on the outer surface of the evaporation unit 7 are equal, and for this reason the heat flux from the building to the environment is 0.

Therefore, heat exchange between the outside environment and the building wall is excluded (temperature difference is 0), which leads to a positive effect:

- reduced energy consumption for heating the building,

- the environmental impact on the environment is reduced,

- the heat losses of the building are recuperated through the fences with the possibility of redistributing heat inside the building,

- it is difficult to detect a building (object) by means of night vision.

Note: at outdoor temperatures below the lower limit of the operating temperature range of the compressor and condenser unit, it is turned off, and the thermal protection of the building is characterized by standard parameters.

Example 2

For buildings located in the climatic subregions of Russia 1A, 1B, 1D, IIB, IIB, IIG and in climatic regions III and IV with an average monthly air temperature in July of 20°C and above, this example illustrates the additional advantages of the proposed device.

The technical parameters of thermal insulation remain the same: the normalized value of heat transfer resistance is R _reg =6.4 m ² ⋅°С / W.

The refrigeration unit FG/FS-665 SZ has again been selected as the condensing unit. Suppose that in the immediate vicinity of a building or structure, temperature sensors record a positive outdoor temperature of plus 5°C, while the standard indoor air temperature remains the same: plus 20°C.

In this case, the automatic control system changes the mode of operation of the refrigeration unit: it maintains the boiling point of freon in the evaporator unit, which is 5-10°C lower than the ambient temperature, for example, minus 5°C. In this case, the heat flow through the heat-shielding enclosure of the building to the surfaces of the heat distribution plate 9, collectors 10 and pipes 11 is proportional to the temperature difference of 25°C, and the heat flow from the environment to the same elements of the evaporative unit is proportional to the temperature difference of 10°C.

The thermal energy of these two flows is combined in the evaporator unit and transferred with the refrigerant vapor to the compressor and condenser unit, where it is released inside the heated room of the building and can be used to heat the main or auxiliary rooms, for example, greenhouses.

In this example, the economic effect is even more significant:

- reduced energy consumption for heating the building due to the heat of the environment,

- energy consumption for heating the building is reduced due to the elimination of heat losses,

- the environmental impact on the environment is reduced,

- the heat losses of the building are recuperated through the fences with the possibility of redistributing heat inside the building.

Claims (3)

1. The device for thermal insulation of buildings and structures, containing a heat-insulating layer and an evaporative unit, characterized in that the compressor and condenser unit is located in a heated room, equipped with a heating system, and the evaporative unit is made in the form of flat finned tubular or sheet-tube heat exchangers, equipped with a boiling pressure regulator refrigerant, installed outside the heat-insulating layer of the building, connected to the compressor-condensing unit of the refrigeration unit, and the evaporating pressure regulator is set to the boiling point of the refrigerant equal to or lower by 5-10°C than the outdoor air temperature. 2. The device according to claim 1, characterized in that the heated room is equipped with an automatic air temperature control system by changing the heat output of the heating system. 3. The device according to claim. 1, characterized in that the heating system has an air or water circuit for transferring the body to the heated room and contains boilers for hydrocarbon fuels, water or electric air heaters.

Images