RU2746382C1 - Heat-insulating flooring for cold floors of building - Google Patents

Abstract

FIELD: construction.SUBSTANCE: invention relates to construction and can be used for insulation of cold floors, namely for floors of cold cellars. Heat-insulating flooring for cold floors of the building contains bars made of strong material with high heat-insulating properties, closed from above with heat-conducting surface sheet, End sections of said bars are closed by perforated sheets adjacent to heat-conducting surface sheet. Between bars there are heat-insulating strips forming air grooves between their upper surface and lower surface of said sheets, wherein the bars and the lower surface of the heat insulating strips of the heat-insulating flooring are laid on the upper surface of the base floor cold-covering so that the orientation of the air grooves and the bars were perpendicular, perforated and heat insulating sheets - parallel to the outer wall, and the edges of the perforated sheets and ends of the bars adjoined the outer and inner walls of the building.EFFECT: invention improves reliability and efficiency of a heat-insulating flooring for cold floors of a building.1 cl, 4 dwg

Description

The invention relates to construction and can be used for insulation of cold ceilings, namely for ceilings of cold basements and buildings with apartment heating and individual houses.

Known underfloor heating, which includes an electric heating system containing heating sections with electric current leads, and in the heating system, the heating sections are made of interconnected tubes, the cavity of which is filled with electrolyte, for example, an aqueous solution of sodium chloride, the tubes are made of a material with a temperature coefficient of linear expansion is much larger than the temperature coefficient of linear expansion of the electrolyte, for example, from polypropylene, and the current leads of the heating sections are made of graphite and are installed symmetrically in the holes of the side tubes of each section and are connected in parallel by current supply buses [RF Patent No. 2431083, IPC F24D 304. 2011].

The main disadvantage of the known warm floor is the complexity of its design and the need to supply the device with electricity, which reduces its reliability, efficiency and safety conditions.

Closer to the proposed invention is a floor heating system for residential and industrial premises, containing supply and return pipelines and means for transferring thermal energy, laid in equally spaced parallel grooves laid in the upper surface of the heating panels, on top of which a heat-conducting surface is installed, characterized in that, that a set of jet pipes, made in the form of separate metal hermetically sealed bodies with evaporation and condensation zones, are placed in the grooves of the heating panels as a means of transferring thermal energy, into the inner cavity of which a liquid heat conductor is pumped under vacuum, and each of these pipes is connected to the supply pipeline at an angle of 2-3 ° relative to the base of the heating panels [RF Patent No. 2357154. IPC F24B3 64.2009].

The main disadvantages of the known system are all the complexity and the need to provide panels with a heat carrier, which reduces its reliability and efficiency.

The technical result achieved by the invention is to increase the reliability and efficiency of the heat-insulating type of us for cold floors of the building.

The technical result is achieved in that the proposed thermal insulation flooring for cold floors of a building contains beams made of durable material with high thermal insulation properties, for example wood, closed on top with a sheet of heat-conducting surface, made, for example, of fiberglass, which has high strength and the value of the thermal conductivity coefficient, between beams placed heat-insulating strips, made, for example, of glass wool, forming air grooves between their upper surface and the lower surface of the heat-conducting sheets, the end sections of which, and the bars are closed with perforated sheets, also made of fiberglass, adjacent to the sheet of the heat-conducting surface, and the bars and the lower the surface of the heat-insulating strips is laid on the upper surface of the cold ceiling of the basement of the first floor in such a way that the orientation of the air grooves and beams is perpendicular, perforated and heat-conducting l istov - parallel to the outer wall, and the edges of the perforated sheets and the ends of the beams adjoined the outer and inner walls of the building.

The proposed thermal insulation flooring for cold building floors (TINHP) is shown in Fig. 1-4 (Fig. 1 - general view of TINHP, Fig. 2-4 - node for joining TINHP with the outer wall).

The proposed TINHP 1 contains beams 2 made of durable material with high thermal insulation properties (for example, wood), closed on top by a sheet of heat-conducting surface 3, made, for example, of fiberglass. possessing high strength and the value of the thermal conductivity coefficient, the end sections of the aforementioned beams 2 are closed with perforated sheets 4, made, for example, also of fiberglass, adjacent to the sheet of heat-conducting surface 3, between the beams 2 are placed heat-insulating strips 5, made, for example, of glass wool [Dolzhikov P.N. V. V. Psyuk, A. A. Shubin Plastic materials and structures in construction: textbook. allowance, Alchevsk: Publishing house of DonSTU "2012, 188 p .: Stradanchenko S.G., Shubin A.A. Plastics in construction: textbook / Shakhtii Institute of SRSTU. Novocherkassk, 2004. 196 pp.], Forming between its upper surface and the lower surface of sheets 3 and 4 air grooves 6, and the longitudinal bars 2 and the lower surface of the thermal insulation strips 5 TINHP 1 are laid on the upper surface of the cold ceiling 6 of the basement 8 of the first floor 9 in such a way conversely, the orientation of the air grooves 6 to the beams 2 is perpendicular, the perforated and heat-insulating sheets 3 and 4 are parallel to the outer wall 10, and the edges of the perforated sheets 4 and the ends of the beams 2 are adjacent to the outer 10 and inner 11 walls of the building.

TIPHP 1 is assembled at the place of installation. First, the beams 2 are laid and between them the heat-insulating strips 5 are placed on the surface of the cold ceiling 6 of the basement 8 of the first floor 9 so that their ends adjoin the outer 10 and inner 11 walls of the building: respectively, after which sheets of the heat-conducting surface 3 and perforated are applied to the beams 2 sheets 4, which are attached to the beams 2 (attachment points are not shown in Figs. 1-4).

For the convenience of installation and transportation of TINHP, the bars 2 can be used not entirely, but in the form of segments, sheets 3 and 4 can be assembled from separate fragments, made, for example, in the form of a square or rectangular tile. The recommended height of TINHP is (80-100) mm. thickness of sheets 3 and 4 - (25-30) mm. the dimensions of the beams are (60 × 30) mm. the thickness of the heat-insulating strips is (25-30 mm) and the height of the grooves is 6 - (30 -35) mm, respectively, the width of the grooves is limited by the strength conditions and the size of the fragments of sheets 3 and 4.

In cold weather the goals of TINHP 1 works as follows. When the heating is turned on in the premises of the first floor 9, a warm air atmosphere is created, but at the same time heat loss occurs through the outer fences 10 and the cold ceiling 7 above the unheated basement 8. In the presence of TINHP 1 on the cold floor 7, heat losses through it are reduced due to thermal insulation strips 5, beams 2, also having thermal insulation properties and an air gap in the grooves 6. At the same time, as a result of the difference between the temperatures of the surfaces of the inner wall 11 (t ₁₁ ) and the outer wall 10 (t ₁₀ ), air circulation occurs in room 9. At the same time, part of the circulating air from the outer wall 10 through the holes in the perforated sheets 4 enters the grooves 6, moves along them, simultaneously heating the sheet of the heat-conducting surface 3 and is removed from them through the holes of the perforated sheets 4 at the inner wall 11. In addition, the sheet is heat-conducting surface 3 is heated from above from contact with the main mass of air in room 9, as a result of which the temperature of the outer surface of the sheet 3 in the rooms of the lower floor 9 rises to the value (t ₁₁ ) The temperature of the surface of the sheet 3 (t ₁₁ ) created as a result of the above processes, although slightly lower than the air temperature in room 9, but much higher than the temperature of the surface of the cold ceiling 7, which increases the comfort conditions in the lower floors of the building,

In the warm period of time, the temperatures of the outer and inner walls 10 and 11 (t ₁₀ ) and (t ₁₁ ) are practically the same, therefore, air circulation is carried out due to ventilation and air conditioning systems and the effect of TINHP 1 is to reduce the floor temperature in the rooms of the lower floor.

'Thus, the proposed thermal insulation flooring for cold floors of a building allows: 10 in winter, due to increased thermal insulation and contact with the room air, to increase the floor temperature of the premises of the lower floor without additional expenditures of thermal or electrical energy, which increases its reliability, efficiency and provides an increase comfortable living conditions for people;

2). in the summer, due to the increased thermal insulation, to reduce heat gain through the lower floors, which ensures a decrease in energy consumption for air conditioning and an increase in comfortable living conditions for people.

Claims (1)

Heat-insulating flooring for cold floors of a building, containing grooves, on top of which a heat-conducting surface is installed, characterized in that the beams made of durable material with high thermal insulation properties, covered from above with a sheet of heat-conducting surface, between the bars are placed heat-insulating strips, forming air grooves between their upper surface and the lower surface of the above-mentioned sheet, the end sections of which and the bars are closed with perforated sheets adjacent to the sheet of heat-conducting surface, which are made of strong material with a high value of the thermal conductivity coefficient, the beams and the above-mentioned sheets of thermal insulation decking are laid on the upper surface of the cold ceiling of the basement of the first floor in such a way that the orientation of the air grooves and beams is perpendicular, the perforated and thermal insulation sheets are parallel to the outer wall, and the edges of the perforated sheets and the ends of the beams adjoined the outer and inner walls of the building.

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