RU2552975C2 - Floor heating (cooling) system - Google Patents

Abstract

FIELD: heating.

SUBSTANCE: invention relates to room floor heating and/or cooling systems and can be used for creation of optimum microclimate parameters in domestic and office buildings and structures. A floor heating (cooling) system containing a heat-insulating layer, a concrete layer with a low-inertia heat exchange coil arranged in it for circulation of a heat carrier or a cooling medium, which is located near the floor surface, a heat-conducting metallic material, additionally contains an accumulation heat exchange coil located deep in the concrete layer, with that, low-inertia and accumulation heat exchange coils are combined with bypass lines provided with gate valves and a circulating pump, and a metal mesh contacting the low-inertia heat exchange coil is used as a heat-conducting material.

EFFECT: invention allows increasing efficiency of use of cold (heat) accumulated in solid mass of the flooring and control of cold (heat) release to maintain the most optimum room microclimate parameters.

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Description

The invention relates to systems for underfloor heating and / or cooling of premises and can be used to create optimal microclimate parameters in residential and office buildings and structures.

A technical solution is known (RU No. 2341627 C1, class E04F 15/00, publ. 2008), which relates to a heated floor, containing a reinforced concrete base installed on the ground, a waterproofing material laid on the reinforced concrete base, and heat insulation, metal mesh, tubular heating elements successively laid located zigzag and attached to a metal mesh, reinforced screed and floor trim elements that it is equipped with a layer of sand 25-30 mm thick, poured on a waterproofing material, and installed over sand with foam concrete blocks located with gaps relative to each other, covered with sand, while the density of thermal insulation laid on foam concrete blocks is 50-200 kg / m ³ and the thickness is not more than 50 mm in an unloaded condition, the screed is made of coarse-grained sand the thickness determined by the formula a≥3b, where a is the thickness of the screed, b is the diameter of the pipes of the heating elements.

The specified invention is intended only for heating floors, in addition, it does not reflect the ability to control the heating system.

Known heat exchange floor design for controlling indoor temperature (FR 2790819 A1, class F24D 3/16, publ. 2001), which contains a metal heat dissipation lattice with a circuit laid thereon for circulation of a heat carrier and a coating with a high coefficient of thermal conductivity.

Known devices for underfloor heating (JP 2895424, F24D 3/16, publ. 2000; JP 3045135, F24D 3/16, publ. 2001) containing a heat-insulating layer with grooves for laying tubes with a circulating coolant, as well as heat-emitting sheet material.

The disadvantage of analogues is the difficulty of controlling the convective heat transfer system, in which thermal energy is exchanged between the liquid and the medium.

Closest to the claimed is a device for heating and / or cooling of premises, such as residential and office buildings (RU No. 2178122 C2, class F24D 3/14, E04B 5/10, publ. 2002), containing a supporting plate on which pipes are laid along which the coolant or cooling medium passes, laid in a heat-conducting layer, while the carrier plate on the side facing the room has a profile that in the cross section has a wavy shape, that is, has protrusions and depressions that pass into each other under pl angle, and the pipes in the section of the depressions of the carrier plate, laid in a heat-conducting layer, pass with a gap from the edge and bottom of the cavity.

The main disadvantage of this technical solution is the thermal inertia and poor controllability of the underfloor heating (cooling) system, especially in the cooling mode, since heat fluxes from the middle of the massive overlap layer propagate much more slowly than the thermal situation in the room changes due to changes in outdoor temperature and solar radiation .

The technical task of the invention is the creation of an adjustable water floor heating (cooling) system, increasing the efficiency of using the cold (heat) accumulated in the array of overlapping and regulating cold transfer (heat transfer) to maintain the most optimal microclimate in the room.

The main difficulty in implementing a combined floor heating and cooling system is that the heating mode has a significantly higher temperature potential than the cooling mode, and for its implementation, a 2-3 times smaller heat transfer surface is needed, so for the heating mode the difference in temperature of the heat carrier and the surface warm floor is 15-20 ° C, while with a standard refrigerant (14/16 ° C), this temperature difference is only 5-6 ° C.

The problem is solved in that the underfloor heating (cooling) system, comprising a heat-insulating layer, a concrete layer with a low-inertia heat exchanger coil placed therein for circulating a heat carrier or cooling medium, located near the floor surface, a heat-conducting metal material, further comprises an accumulation heat-exchange coil located in the depth of the concrete layer, while the low-inertia and accumulative heat-exchange coils are combined by bypass lines equipped with valves and a circulation pump, and as a heat-conducting material contains a metal mesh in contact with a low-inertia heat-exchange coil.

The invention is illustrated in more detail by the drawings and description thereof.

Figure 1 shows a cross section of a concrete floor; figure 2 - system of floor heating (cooling).

The underfloor heating (cooling) system comprises a heat-insulating layer 1, a concrete layer 2, in which a low-inertia heat-exchange coil 3 is placed for circulating a heat carrier or a cooling medium in contact with a heat-conducting material - metal mesh 4 and located near the floor surface, and an accumulation heat-exchange coil 5 located deep in the concrete layer, while the low-inertia heat-exchange coil 3 and the accumulation heat-exchange coil 5 are combined bypass lines 6, equipped with valves 7 and a circulation pump 8, also a low-inertia heat-exchange coil 3 is equipped with valves 9, and an accumulation heat-exchange coil 5 is equipped with valves 10. A metal mesh 4 in contact with a low-inertia heat-exchange coil 3 improves the uniform distribution of heat over the entire floor surface.

The system of floor heating (cooling) operates as follows.

In the charging mode with cold (warmth) of the overlap structure (Fig. 1), the coolant (coolant) enters the low-inertia heat-exchange coil 3 (Fig. 2) with open valves 9 and into the accumulation heat-exchange coil 5 with open valves 10, and valves 7 of bypass lines 6 closed, and the circulation pump 8 is turned off. In the discharge mode, the cold (heat) from the accumulation heat transfer coil 5 is transferred to the low-inertia heat transfer coil 3 using the circulation pump 8 with open valves 7 of the bypass lines 6 and closed valves of the heat transfer coils 9 and 10.

The combination of accumulation 5 and low-inertia 3 heat exchange circuits bypass lines 6 with a circulation pump 8 allows you to quickly transfer the cold (heat) from the middle of the array of the ceiling structure to the floor surface. At the same time, in the daytime it is not required to use a refrigerating machine to generate cold (an electric boiler for heating), but it is enough to use the accumulated energy in an adjustable mode. Refrigeration (heat transfer) of the floor is controlled by the sensors of the resulting temperature installed in the room due to changes in the performance of the circulation pump. In winter, only one coil works, and in the summer - both coils. Comfortable floor surface temperature in the cold season + 25-26 ° C, in the warm + 20-21 ° C. The maintenance of such temperatures provides compensation for heat loss in the cold season and heat input in the warm season.

A significant economic advantage of the combined floor cooling (heating) system is the ability to charge with cold (heat) at night at a reduced tariff for electricity (in most regions it is 2-4 times less than the daily rate).

The claimed heating (cooling) system has several advantages over traditional ones (radiators, convectors, fan coils, split systems): silent; does not create undesirable temperature gradients and air velocity in the room; saves energy; does not occupy a useful volume of premises; allows you to accumulate cold (heat) at night. The device of a floor heating (cooling) system with two-level heat-exchange coils located one (low-inertia heat-exchange coil) near the floor surface, the other (accumulation heat-exchange coil) - in the middle of the ceiling array, solves the problem of controlling the floor heating (cooling) system in which heat is exchanged energy between the liquid and the medium.

Claims (1)

An underfloor heating (cooling) system comprising a heat-insulating layer, a concrete layer with a heat exchanger coil placed therein for circulating a heat carrier or a cooling medium located near the floor surface, a heat-conducting metal material, characterized in that it further comprises an accumulation heat exchanger coil located in the depth of the concrete layer wherein the heat exchange coil for circulating the coolant or the cooling medium and the storage heat exchange coil are combined by bypass lines E provided with valves and circulation pump, as well as the thermally conductive material comprises a metal grid in contact with the heat exchange coil for the circulation of the coolant or cooling medium.

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