RU2808884C1 - Room heating system - Google Patents

Abstract

FIELD: heating.

SUBSTANCE: water heating system built into the floor, characterized by the release of hot air into the heated space. The room heating system includes a pipe for circulation of coolant in it, configured to be placed in at least one gap limited by the floor covering, subfloor and rod-shaped elements fixed between the floor covering and the subfloor, and an air duct configured to be placed between the floor covering and a subfloor having an inlet for supplying air from outside the room and at least one hole for supplying air into the space between the floor covering and the subfloor for heat exchange with a pipe for circulating coolant in it. In this case, holes are made in the floor covering to allow air to escape from the space between the floor covering and the subfloor into the room.

EFFECT: possibility of continuous supply of fresh air for subsequent heating and supply of heated fresh air into the room by combining the ventilation system and the room heating system.

11 cl, 1 dwg

Description

The claimed technical solution relates to the field of space heating, in particular a water heating system built into the floor, characterized by the release of hot air into the heated space.

Space heating systems built into the floor have a number of advantages in contrast to radiator heating, in particular, they provide uniform heating of the room, especially in the floor area, in contrast to the point placement of heating radiators. This increases the comfort of staying indoors, especially in a private home, due to the constantly heated floor, which prevents the negative impact of cold surfaces on the feet and the human body as a whole. In addition, uniform heating of the room is ensured by the convection movement of hot air from the floor to the ceiling, warming the entire space of the room, whereas in the case of radiator heating, heat rises along the walls, not providing comfortable heating of the floor. At the same time, the heating system built into the floor also allows you to warm up the furniture and dry the air in hard-to-reach corners of the room, for example, the spaces behind the furniture, which prevents the growth of mold and mildew, which negatively affect human health and also lead to damage to the furniture. Thus, the development of heating systems built into the floor is a relevant and in demand task at the present time.

A solution known in the prior art is a floor comprising a base having no ventilation holes and formed on a concrete slab, a plurality of lattice posts spaced at appropriate intervals on the concrete slab, and an airtight floor space formed between the concrete slab and the base. The floor structure also includes a base plate mounted on the base, a plurality of spacers located at predetermined intervals on the support plate, and a heat-resistant floor material laid on the spacers such that the spacers are located between the base plate and the heat-resistant floor material. In the space between the gaskets there is a pipe with a coolant, and ventilation holes into the room are made in the floor structure in places close to the corners of the room and are separated from each other to ensure natural convection between the interior space and the space under the floor. Japanese Patent No. JP 3215580 U, IPC E04B 1/76, E04F 15/18, publ. 03/29/2018.

The prior art also knows a technical solution, selected as the closest analogue, related to the design of a module for underfloor water heating systems, which can be used in the production of water floor heating systems in premises for various purposes. The module for an underfloor water heating system includes a deck made of separate profiled boards interconnected with a tongue-and-groove lock, metallized tape, a cross-linked polyethylene pipe in contact with the metallized tape, a heat-accumulating cement-bonded particle board, a finishing coating and a deck support platform. Profiled boards are used with a cross-sectional size of 35×130 mm. Each board has additional transverse and longitudinal grooves on the sides facing the room. The transverse grooves have a rectangular cross-section, and in the laid flooring they are combined into transverse channels. Longitudinal grooves are made with different sections. In this case, the boards laid in the flooring along its periphery and in the middle part have three grooves, and the rest have one groove. The module additionally includes floor gratings installed along the periphery of the flooring, above the transverse channels and at the level of the final coating of the module. RF Patent No. RU 2737983 C2, IPC F24D 3/14, F24D 3/00, F24D 3/12, publ. 07.12.2020.

The disadvantages of the presented level of technology are the low degree of uniformity of heating of the floor and air in the room, as a result of which there may be cold areas on the floor surface, and heating is carried out only in the area where the pipe with the coolant passes. In addition, the optimal speed of heating the room is also not ensured, due to the lack of directional movement of air and its movement only due to natural convection, and there is also no possibility of supplying fresh heated air to the room.

The objective of the claimed technical solution is to create a room heating system that ensures uniform and rapid heating of the room.

The technical result of the proposed solution is to increase the speed and uniformity of heating of the floor covering and air to the required temperature, as well as to increase the efficiency of the heating system, in particular by reducing heat loss. The technical result also consists in the possibility of continuous supply of fresh air for subsequent heating and supply of heated fresh air into the room by combining the ventilation system and the room heating system.

The stated technical results are achieved due to the fact that the room heating system includes a pipe for circulating coolant in it, configured to be placed in at least one gap limited by the floor covering, the subfloor and rod-shaped elements fixed between the floor covering and the subfloor, and an air duct configured to be placed between the floor covering and the subfloor, having an inlet for supplying air from outside the room and at least one hole for supplying air into the space between the floor covering and the subfloor for heat exchange with a pipe for circulating coolant in it, while in The floor covering has holes for air to escape from the space between the floor covering and the subfloor into the room. The pipe for circulating coolant in it is preferably installed on thermal distribution plates installed on the subfloor. Preferably, the gap is made with a height of 30-70 mm and a width of 200-300 mm. The pipe for coolant circulation in it is preferably made with bends to be placed in two or more gaps. The pipe for circulating coolant in it can be made of cross-linked polyethylene. The pipe for circulating coolant in it can be made with a diameter of 16-20 mm. The air duct is preferably configured to connect to the recuperator of the room ventilation system. The inlet part of the air duct can be connected to the ventilation duct of the ventilation system and to the recuperator built into it. The space heating system preferably includes a heat-reflecting coating secured under the pipe to circulate coolant through it. The pipe for circulating coolant in it is preferably secured in clips installed on the subfloor. The space heating system preferably includes thermal distribution plates mounted on top of the pipe to circulate coolant through it.

The use of a pipe in the heating system for circulation of coolant in it is necessary to ensure the intended purpose of the proposed solution and to heat the room by heating the floor covering, as well as the air in the space between the subfloor and the floor covering, which enters the room through holes in the floor covering and warms the room . In contrast to the use of an electric cable as a heat source in the space between the floor covering and the subfloor, which, in the case of sharp turns or bends of the laid cable, can lead to local overheating of the cable and the surface of the floor covering, which reduces the uniformity of heating of the floor covering, as well as can lead to a quick failure of the cable due to its burnout; the use of a pipe for circulating coolant in it does not have such disadvantages, since a coolant is used for heating, not electric current, which increases the uniformity of heating of the floor covering. In addition, in the case of using an electric cable as a heat source, when installing, for example, furniture without legs or additional carpeting on such a floor, local overheating of the heating cable may also occur due to the difficulty of heat removal from the surface of the floor covering, which also results in the uniformity of heating of the floor covering is reduced, and the durability of the proposed heating system is further reduced due to possible cable burnout. In preferred embodiments, water or antifreeze can be used as a coolant for circulation in the pipe.

The formation of at least one gap, limited by the floor covering, the subfloor and the rod-shaped elements fixed between the floor covering and the subfloor, helps to divide the space between the subfloor and the floor covering into small areas in which the air is heated by heat exchange with the pipe for circulation therein The coolant is provided faster due to the smaller volume of air in the gap, thereby the rate of heating of the air, and as a result of the room, increases. Also, making a pipe for coolant circulation in it with the possibility of placement in at least one gap ensures high uniformity of heating of the floor covering by increasing the length and surface area of the pipe for heat exchange with air, as well as by fractional heating of the air, i.e. parts in several gaps, which increases the rate of heating of the floor covering and air. At the same time, when making one gap and placing a pipe in it for coolant circulation, the rate of heating of the air in the gap also increases due to limiting the volume of heated air in the space between the floor covering and the subfloor, as well as constant mixing of air masses as air moves through the hole in the air duct . At the same time, with an increase in the number of gaps, as well as a pipe for circulating coolant in it with the possibility of placing in a larger number of gaps, the rate of heating of the air and the floor covering increases proportionally, due to a decrease in the volume of heated air, an increase in portions of simultaneously heated air and an increase in the surface area of the pipe , giving off heat. In addition, limiting the gap with rod-shaped elements reduces heat loss for heating the foundation or walls of the room, or the gradually cooling coolant in the pipe, in the case of a close location of a part of the pipe with a more heated coolant and a less heated one, i.e. the return part of the pipe, by physically separating the space, preventing the transfer of heat from the more heated part of the pipe to the less heated one, which increases the rate of heating of the floor covering and air in the gap and the efficiency of the heating system by reducing heat loss. At the same time, fixing rod-shaped elements between the subfloor and the floor covering further increases the reliability of the heating system due to the formation of additional stiffening ribs, which reduce the likelihood of bending and damage to the floor covering under high weight loads, for example, the installation of heavy furniture. The rod-shaped elements in the preferred embodiment of the inventive room heating system can be made of wood, which, due to lower thermal conductivity than, for example, brick or reinforced concrete structures, further reduces heat loss for heating the material of the rod-shaped elements and further increases the efficiency of the heating system.

The space heating system also includes an air duct configured to be located between the floor covering and the subfloor, having an inlet for supplying air from outside the room and at least one opening for supplying air into the space between the floor covering and the subfloor for heat exchange with the pipe for circulation therein. coolant. The execution of the air duct with the possibility of placement between the floor covering and the subfloor facilitates the forced and directed supply of air into the space between the floor covering and the subfloor through at least one hole in the air duct to ensure heat exchange between the air and the pipe for circulation of the coolant in it, which increases the rate of heating of the floor coating, as well as air, due to forced air movement, constant mixing of air masses and creating conditions for forced convection, which occurs faster than natural, thereby warming up the air in the room faster. In addition, providing more than one opening to supply air into the space between the floor covering and the subfloor also speeds up the heating of the air in the room by increasing the volume of air supplied from the duct, thereby promoting the mixing of air masses, evenly distributing heat and increasing the uniformity of air heating. Providing a duct with an inlet for supplying air from outside the room also facilitates the forced, directed and continuous supply of fresh air from outside the room into the space between the subfloor and the floor covering due to rapid air movement, for example, due to wind or a fan drawing in air from outside the room, which speeds up the process of heating the air due to forced mixing of air masses, thereby increasing the uniformity of heating. In addition, the presence of an air duct configured to be placed between the floor covering and the subfloor, having an inlet for supplying air from outside the room and at least one hole for supplying air into the space between the floor covering and the subfloor for heat exchange with a pipe for circulating coolant in it allows you to combine the heating system and the room ventilation system to ensure the possibility of continuous supply of fresh air from outside the room into the space between the subfloor and the floor covering for subsequent heating and supply of heated fresh air into the room. The entrance for supplying air from outside the room in preferred embodiments can be made, for example, in the form of an vent to which an air duct is connected, as well as in the form of an vent with an installed fan. In addition, the air duct is preferably configured to connect to the recuperator of the room ventilation system, which further increases the rate of heating of the room due to the entry of pre-heated air from the recuperator through the air duct into the space between the subfloor and the floor covering. The inlet part of the air duct can also be connected to the ventilation duct of the ventilation system and with a recuperator built into it, which, due to the movement of air through the ventilation duct at high speed to ensure ventilation of the room, further increases the uniformity of air heating by increasing the frequency of mixing of air masses in the space between the floor covering and subfloor by connecting the inlet part of the air duct to the ventilation duct.

Making holes in the floor covering to allow air to escape from the space between the floor covering and the subfloor into the room is necessary directly to increase the rate of heating of the room due to the entry of warm air into the room space. In the absence of holes in the floor covering, the heating of the room would be less efficient, since it would be carried out only due to the heating of the floor covering and natural convection of air in the room, whereas when warm air exits through the holes in the floor covering in addition to the heated floor covering, the heating of the room accelerates . In a preferred embodiment, a decorative mesh can be installed in the holes in the flooring to allow air to escape from the space between the flooring and the subfloor into the room, which reduces the likelihood of debris getting into the space between the flooring and the subfloor, which can additionally reduce the uniformity and rate of heating of the room by creating a physical obstacle in the path of warm air. Additionally, in preferred embodiments, the openings in the flooring may be located near walls, doorways or under windows.

In a preferred embodiment, the coolant circulation pipe is installed on thermal distribution plates installed on the subfloor, which, due to being made of a material with high thermal conductivity, preferably metal, easily accept heat flow upon contact with the coolant circulation pipe and further increase the heated surface area for heat exchange with air in the gap between the subfloor and the floor covering, which further increases the rate of air heating. At the same time, the preferable use of thermal distribution plates for installing a pipe on them for circulation of the coolant also further increases the uniformity of heating of the floor covering due to the possibility of uniform laying of the pipe when using multiple plates that have a groove in the central part, or are made in the form of an Ω-profile for installing the pipe. In addition, in a preferred embodiment, the room heating system includes a heat-reflecting coating fixed under the pipe for circulating coolant in it, which, due to its properties, reflects the heat flow emanating from the pipe for circulating coolant in it, reducing the likelihood of heat loss for heating the subfloor, thereby , further increasing the efficiency of the heating system, and as a consequence the rate of heating of the air in the gap, as well as the floor covering. Foil or foil insulation can preferably be used as a heat-reflecting coating, which helps to additionally retain heat in the space between the floor covering and the subfloor due to its thermal insulation properties, thereby further reducing heat loss and increasing the efficiency of the heating system.

The pipe for coolant circulation in it is preferably made with bends to be placed in two or more gaps, which further increases the uniformity of heating of the floor covering, due to the possibility of placing the pipe over a larger area of the subfloor, which also further increases the rate of air heating. In addition, the preferred design of the pipe with bends makes it possible to place the pipe for circulation of the coolant in the corner parts of the space under the floor, reducing the likelihood of cold areas of the floor covering and further reducing the uniformity of heating of the room. In a preferred embodiment, laying a pipe for circulation of coolant in two or more gaps can be done as a “snake” or “double snake”. In addition, the pipe for circulating coolant in it can preferably be made of cross-linked polyethylene, which, due to its low thermal conductivity, further increases the uniformity of heat transfer from the coolant to the air throughout the entire pipe, in contrast to making pipes from metal, which has high thermal conductivity, as a result of which By the end of the pipe circuit, the coolant will give up a significant amount of heat and cool down, which will further reduce the uniformity of heating of the floor covering and air, forming cold areas, thus further increasing the uniformity of heating of the floor covering and air. In addition, the preferable design of the pipe for the circulation of coolant in it from cross-linked polyethylene reduces the likelihood of the tube becoming overgrown with sediment and plaque, narrowing the lumen of the pipe and making it difficult for the coolant to pass through it and further reducing the uniformity of heating of the floor covering and air by reducing the amount of coolant in the pipe, thus This also further increases the uniformity and speed of heating of the floor covering and air. At the same time, due to lower thermal conductivity than metal, cross-linked polyethylene reduces the likelihood of condensation forming on the surface of the pipe, which in the preferred embodiment further increases the reliability and safety of the room heating system due to the fact that a large amount of condensate can lead to an increase in the importance of air, as well as the development of mold in the space between the subfloor and the floor covering, spores of which can be spread by air currents and have a negative impact on human health, and mold can also destroy the materials of the floor covering and rod-shaped elements, further reducing the reliability of the heating system. In addition, cross-linked polyethylene has a lower coefficient of thermal expansion, unlike metal, which preferably reduces the likelihood of pipe failure due to uneven expansion and possible loss of integrity, thus further increasing the reliability and durability of the system, since the pipe for circulation in it The coolant practically does not change its linear dimensions when using a heated coolant, and does not burst when the coolant freezes, for example, when the heating system is not used for a long time in winter.

In a preferred embodiment, the pipe for coolant circulation in it can be made with a diameter of 16-20 mm. In the case of preferential use of a pipe for circulating coolant in it with a diameter of less than 16 mm, the volume of coolant circulating in the pipe is further reduced, which further reduces the rate of heating of the floor covering and air in the room due to less heat. In addition, the preferred diameter of the pipe for circulating coolant in it is less than 16 mm, which further reduces the surface area of the pipe, due to which heat exchange with air occurs, which also further reduces the rate of heating of the air. At the same time, the preferred use of a pipe for circulating coolant in it with a diameter of more than 20 mm further reduces the distance from the pipe to the rod-shaped elements, as a result of which the probability of heat loss for heating the material from which the rod-shaped elements are made increases, which further reduces the efficiency of the heating system. In addition, with the preferred use of a pipe for circulating coolant in it with a diameter of more than 20 mm, the speed of movement of the coolant in the pipe decreases, which additionally contributes to uneven heating of the floor covering and air due to the fact that a less heated coolant will reach the end of the pipe circuit, since due to the low speed of movement of the coolant, the likelihood of it cooling before it passes through the entire circuit increases. Thus, the preferable use of a pipe for circulating coolant with a diameter of 16-20 mm further increases the uniformity of heating of the floor covering and air and the heating rate by further increasing the uniformity of heat transfer throughout the entire contour of the pipe. In addition, in the preferred embodiment, using a pipe for circulating coolant in it with a diameter of more than 20 mm further increases the minimum radius of curvature of the pipe, thereby increasing the need to increase the distance between the rod-shaped elements if it is necessary to place the pipe in several gaps to reduce the likelihood of damage to the integrity of the pipe when bending , as a result of which the likelihood of sagging and damage to the floor covering increases, which further reduces the reliability of the heating system.

Preferably, the gap limited by the floor covering, the subfloor and the rod-shaped elements fixed between the floor covering and the subfloor further increases the speed and uniformity of heating of the floor covering and the air in the room, while further reducing heat loss, when performed with a height of 30-70 mm, width 200-300 mm. If it is preferable to make a gap with a height of less than 30 mm, the likelihood of uneven heating of the floor covering increases due to its close location to the surface of the pipe, which increases the likelihood of unheated areas of the floor covering and overheated areas directly above the pipe for coolant circulation in it, which further reduces the uniformity of heating floor covering. When it is preferable to make a gap with a height of more than 70 mm, the time additionally increases and the rate of air heating decreases due to an additional increase in the volume of air in the gap, which requires more time to warm up. When it is preferable to make a gap with a width of less than 200 mm, the heat loss for heating the rod-shaped elements limiting the gap due to an additional reduction in the distance between them, and as a consequence of the distance to the pipe for circulation with the coolant, further increases, thereby further reducing the efficiency of the heating system. When it is preferable to make a gap with a width of more than 300 mm, the time additionally increases and the rate of air heating decreases due to an additional increase in the volume of air in the gap, which requires more time to warm up. Thus, the preferred implementation of a gap with a height of 30-70 mm and a width of 200-300 mm further increases the efficiency of the room heating system and further increases the uniformity and speed of heating of the floor covering and air in the room.

In a preferred embodiment, the pipe for circulation of coolant in it can be secured in clips installed on the subfloor, due to which the surface area of the pipe for circulation of coolant in it, with which heat is exchanged with air, is further increased, due to the lack of contact of the pipe with the surface of the subfloor, which further increases the rate of heating of the floor covering and the air in the room, and also further reduces heat loss for heating the subfloor, which further increases the efficiency of the proposed heating system. In a preferred embodiment, the clips installed on the subfloor may be made of a polymeric material and represent a clamp for a pipe of the appropriate diameter, containing a support for attaching the clamp to the surface of the subfloor, due to which the pipe is located above the surface of the subfloor. The clips can also preferably contain top latches, which further increase the reliability of fastening the pipe for circulation of coolant in the clips and reduce the likelihood of its disconnection due to possible bending of the pipe due to the heated coolant. In addition, in a preferred embodiment, the room heating system includes thermal distribution plates installed on top of the pipe for coolant circulation in it, which further increases the speed and uniformity of heating of the floor covering, and as a result of the air in the room, due to the fact that the thermal distribution plates are made of material with high thermal conductivity, preferably metal, and easily accept heat flow upon contact with the pipe for coolant circulation and additionally increase the heated surface area for heat exchange with air in the gap between the subfloor and the floor covering, which further increases the rate of air heating. At the same time, the preferable use of thermal distribution plates and installing them specifically on top of the pipe for coolant circulation in it further increases the uniformity of heating of the floor covering by increasing the surface area from which heat is exchanged with air or directly with the floor covering when it comes into contact with the thermal distribution plates. At the same time, the preferred design of the room heating system, which includes thermal distribution plates installed on top of the pipe for circulation of coolant in it, further increases its efficiency by further reducing the likelihood of heat loss from the thermal distribution plate to heat the subfloor due to the installation of thermal distribution plates precisely on top of the pipe for circulation in coolant. At the same time, with the preferred installation of thermal distribution plates on top of the pipe for circulation of coolant in it, while fixed in clips installed on the subfloor, the amount of heat loss for heating the subfloor is further reduced, which further increases the efficiency of the room heating system due to the absence of direct contact between the pipe and subfloor, and also further increases the speed and uniformity of heating of the floor covering and air in the room by increasing the surface area for heat exchange by installing thermal distribution plates on top of the pipe to circulate the coolant in it.

Next, the claimed technical solution is explained using a figure that shows the preferred embodiment of a room heating system in cross-section.

The numbers on the figures indicate:

- pipe (1) for circulation of coolant in it;

- gap (2);

- flooring (3);

- subfloor (4);

- rod-shaped elements (5);

- air duct (6);

- a hole (7) made in the air duct (6) to supply air into the space between the floor covering (3) and the subfloor (4);

- a hole (8) made in the floor covering (3) to allow air to escape from the space between the floor covering (3) and the subfloor (4) into the room;

- bending (9) of the pipe (1) for circulation of coolant in it.

Below, with reference to the figure, one of the preferred embodiments of the proposed technical solution is described.

The room heating system includes a pipe (1) for circulating coolant in it, configured to be placed in at least one gap (2) limited by the floor covering (3), subfloor (4) and rod-shaped elements (5) fixed between the floor coating (3) and subfloor (4). The room heating system also includes an air duct (6) configured to be placed between the floor covering (3) and the subfloor (4), having an inlet for supplying air from outside the room and at least one hole (7) for supplying air into the space between the floor coating (3) and subfloor (4) for heat exchange with the pipe (1) for coolant circulation in it. The floor covering (3) has holes (8), preferably with decorative mesh installed, to allow air to escape from the space between the floor covering (3) and the subfloor (4) into the room. Preferably, the gap (2) is made with a height of 30-70 mm and a width of 200-300 mm. The pipe for coolant circulation in it is preferably made with bends (9) to be placed in two or more gaps (2). In a preferred embodiment, the pipe (1) for circulating coolant in it can be made of cross-linked polyethylene with a diameter of 16-20 mm. The air duct (6) is preferably configured to connect to the recuperator of the room ventilation system. The space heating system preferably includes a heat-reflecting coating secured under the pipe (1) to circulate coolant through it.

The following describes the preferred options for operating the proposed technical solution.

To use the heating system for its intended purpose, rod-shaped elements (5) are installed on the subfloor (4), forming and limiting the gap (2). Preferably, the gap (2) is made with a height of 30-70 mm and a width of 200-300 mm. A pipe (1) is placed in at least one gap for coolant circulation in it, preferably made with bends (9), under which a heat-reflecting coating, for example, foil insulation, is preferably fixed. An air duct (6) is also installed on the subfloor (4), preferably connected to a recuperator of the room ventilation system for air supply, having at least one hole (7) for supplying air into the space between the floor covering (3) and the subfloor ( 4) for heat exchange with pipe (1) for coolant circulation in it. The floor covering (3) is then installed, including holes (8), preferably with decorative mesh installed, to allow air to escape from the space between the floor covering (3) and the subfloor (4) into the room. The air entering the air duct (6) exits through the holes (7) into the space between the subfloor (4) and the floor covering (3), and moves into the gaps (2), in which it exchanges heat with the pipe (1) for circulation there is coolant in it. Then the heated air, due to the constant movement of air masses from the air duct into the space between the subfloor (4) and the floor covering (3), enters the room through the holes (8) made in the floor covering (3), due to which the room is heated. In addition, due to the constant presence of warm air in the space between the subfloor (4) and the floor covering (3), the floor covering is heated, which also accelerates the heating of the room due to the natural convection of air heated near the floor covering.

The inventive technical solution can be used for heating a room, as well as for heating the floor in a room to create comfortable living conditions. The solution is characterized by increased speed and uniformity of heating of the floor covering and air, as well as increased efficiency.

The presented figures, description of the design and use of the room heating system do not exhaust the possible design options and do not limit in any way the scope of the proposed technical solution. Other embodiments are possible within the scope of the claimed formula.

Claims (11)

1. A room heating system, including a pipe for circulating coolant in it, configured to be placed in at least one gap limited by the floor covering, subfloor and rod-shaped elements fixed between the floor covering and subfloor, and an air duct configured to accommodate between the floor covering and the subfloor, having an inlet for supplying air from outside the room and at least one hole for supplying air into the space between the floor covering and the subfloor for heat exchange with a pipe for circulating coolant in it, with exit holes made in the floor covering air from the space between the floor covering and the subfloor into the room. 2. The room heating system according to claim 1, characterized in that the pipe for circulating coolant in it is installed on thermal distribution plates installed on the subfloor. 3. The room heating system according to claim 1, characterized in that the gap is made with a height of 30-70 mm and a width of 200-300 mm. 4. The room heating system according to claim 1, characterized in that the pipe for coolant circulation in it is made with bends for placement in two or more gaps. 5. The room heating system according to claim 1, characterized in that the pipe for circulating coolant in it is made of cross-linked polyethylene. 6. The room heating system according to claim 1, characterized in that the pipe for circulating coolant in it is made with a diameter of 16-20 mm. 7. The room heating system according to claim 1, characterized in that the air duct is designed to be connected to the recuperator of the room ventilation system. 8. The room heating system according to claim 1, characterized in that the inlet part of the air duct is connected to the ventilation duct of the ventilation system and with a recuperator built into it. 9. The room heating system according to claim 1, characterized in that it includes a heat-reflecting coating fixed under the pipe for coolant circulation in it. 10. The room heating system according to claim 1, characterized in that the pipe for circulating coolant in it is fixed in clips installed on the subfloor. 11. Room heating system according to paragraphs. 1 and 10, characterized in that it includes thermal distribution plates installed on top of the pipe for coolant circulation in it.