RU172869U1 - Panel for underfloor heating - Google Patents

Abstract

The utility model relates to the field of construction, namely the construction of energy-efficient structures, and can be used to provide high thermal performance of space heating and create a microclimate in residential, industrial and warehouse premises, in livestock farms, in greenhouses for soil heating. model is to create a reliable, safe and versatile panel for underfloor heating, with high environmental cleanliness and efficiency. The fact is that in the proposed solution, the panel is multilayer with heat-insulating and heat-accumulating layers of a homogeneous material, and the thermal element is made in the form of a corrugated thin-walled tube and placed in the heat-accumulating layer, inside the thermal element there is a heating element in the form of a wire or spiral, and the thermal element is placed in the panel in the form of parallel rows with a pitch of 250-350 mm and is oriented either along or across the panel. In addition, the thermal element is placed in the heat-accumulating layer between using reinforcing grids that are installed on the spacers, and the heating element is made of heat-resistant and chemically resistant alloyed with rare-earth metals, and the free interior of the thermal element is filled with a finely divided mixture of non-conductive electricity, refractory, refractory materials. In addition, the heat-insulating layer and the heat-accumulating layer of the heating mate made of encapsulated porous aggregate, at least expanded clay, and the insulating layer in filled with a filler of fractions of 5-16 mm and a thickness of at least 20 mm., the heat storage layer is made of a filler of fractions of 3-10 mm and a thickness of at least 30 mm, and at least 3.5 diameters of the heat element. In addition, the corrugated thin-walled tube of the heat the element is made mainly of stainless steel, the heating element is made mainly of nichrome, and the interior of the thermal element is filled with a ceramic mixture, mainly magnesium oxide MgO. 3 s.p. f-ly, 3 ill.

Description

The utility model relates to the field of construction, namely the construction of energy-efficient structures, and can be used to provide high thermal performance of space heating and create a microclimate in residential, industrial and warehouse premises, in livestock farms, in greenhouses for soil heating.

Known electrically heated floor according to the patent of the Russian Federation No. 2144612, class. E04F 15/18, 1999, containing a base, heat-insulating, underlining, heat-accumulating layers, a coating and heating elements in the form of carbon tapes connected in parallel, located between the underlying layers. Carbon tapes have a width of 15-100 mm and a linear electrical resistance of 2-20 Ohm / m, while the ratio of tape width to length is 1: 10-1: 125, and the ratio of the total tape area to floor area is 0.2-0, 9.

The electrically heated floor of this design, providing a comfortable thermal regime on the floor surface, is safe due to the use of ultra-low voltage of 12 or 24 V, is environmentally friendly, durable and reliable in operation, since carbon tapes are used as heating elements at a temperature of 50-70 ° С on the surface tapes can work continuously for more than 40 years, it saves energy due to the optimal choice of geometric ratios of carbon tapes.

However, the known electrically heated floor is made monolithic on a single basis, the structural solution of which is much far from the claimed panel.

Known heated floor panel according to the patent of the Russian Federation No. 2313645, class. E04F 15/04, 2006, adopted by the applicant for the prototype. It is made, in particular, of a layered material, has side edges on which the elements of the connecting device of the panels for connecting with adjacent panels are made. To install and use such a panel in a floor heating system, it is proposed to fix heating means on its lower surface and to make a connecting element for the heater on at least one of the indicated side edges.

This solution relates to floor panels, which are available on the market in large quantities and intended for the manufacture of floor coverings.

Such floor panels are especially suitable for laying on top of a floor heater. Previously, floor heaters and floor coverings could only be installed by professional workers.

However, this heated panel is a somewhat outdated design, and the panel connecting elements and plug elements of the heater connecting element look unreliable. This solution has low heat transfer efficiency, since the heated panel is made of dissimilar materials, and heat loss is always present between layers of different materials.

The technical task of the proposed utility model is to create a reliable, safe and versatile panel for a warm floor with high environmental cleanliness and efficiency.

The problem is solved in that in the proposed solution, the panel is multilayer with heat-insulating and heat-accumulating layers of a homogeneous material, and the thermal element is made in the form of a corrugated thin-walled tube and placed in the heat-accumulating layer, inside the thermal element there is a heating element in the form of a wire or a spiral, and the thermal the element is placed in the panel in the form of parallel rows with a pitch of 250-350 mm and is oriented either along or across the panel.

In addition, the thermal element is placed in a heat-accumulating layer between two reinforcing grids that are mounted on the spacers, and the heating element is made of a heat-resistant and chemically resistant alloy doped with rare-earth metals, and the free interior of the thermal element is filled with a finely ground mixture of non-conductive electricity, refractory, refractory materials.

In addition, the heat-insulating layer and the heat-accumulating layer of the heating mat are made of encapsulated porous aggregate, at least expanded clay, and the heat-insulating layer is made of aggregate fractions of 5-16 mm and a thickness of at least 20 mm, the heat-accumulating layer is made of aggregate fractions of 3-10 mm and at least 30 mm thick, and at least 3.5 diameters of the thermal element.

In addition, the corrugated thin-walled tube of the thermal element is mainly made of stainless steel, the heating element is mainly made of nichrome, and the interior of the thermal element is filled with a ceramic mixture, mainly magnesium oxide MgO.

The technical result from the use of the proposed technical solution is that due to the proposed design of the panel for the manufacture of a warm heated floor, its heating temperature is evenly distributed over the entire area of the mounted floor, thereby increasing the efficiency and thermal performance of the floor and reducing the cost of manufacturing and installation of the floor.

In FIG. 1 shows stacked modular panels for underfloor heating with options for placing thermal elements in them either along or across the panel;

in FIG. 2 is a section A-A of a typesetting modular underfloor heating panel in FIG. one;

in FIG. 3 is a sectional view of a section of a building with a warm floor.

The creation of a comfortable building begins with the development of a project in which the parameters of all elements of the building, the microclimate conditions, including ventilation and heating, are laid. Much attention is paid to maintaining the desired temperature in the premises of the building and structure.

The panel for the warm floor is multilayer with a heat-insulating layer 1 and a heat-accumulating layer 2, and the thermal element 3 is made in the form of a corrugated thin-walled tube, mainly stainless steel, and is placed in the heat-accumulating layer 2 between two reinforcing grids 4 and 5, which are installed on the spacers 6 Inside the thermal element 3, a heating element 7 is placed in the form of a wire or spiral, which is made of a heat-resistant and chemically resistant alloy doped with rare-earth metals, mainly of nichrome X20H80, and the free inner space of the thermal element is filled with a finely divided mixture of non-conductive electricity, refractory, refractory materials, mainly magnesium oxide MgO.

Magnesium oxide serves as a heat conductor from the heating wire or spiral to the walls of the thermal element 3. In this assembled state, the thermal element 3 undergoes radial rolling, as a result of which its diameter decreases, and the filler in the thermal element 3 is compacted. Such a technological operation allows, when voltage is applied to the thermal element 3, it instantly warms up to it and cool for a long time when the power is turned off.

The panel for the warm floor is made of modular multilayer, the lower layer of which is the heat-insulating layer 1, and the upper layer is the heat-accumulating layer 2. The panel is designed to cover the prepared floor 8 of the room, transfer heat and further heat it. Thermal elements 3 of the installed modular panels can be connected to the power cable in parallel or in series, and the installed modular panels form a heated floor. But the parallel connection of the thermal elements 3 to the power network cable is most preferable.

The heat-insulating layer 1 and the heat-accumulating layer 2 are made of a homogeneous material, namely, encapsulated porous aggregate, mainly expanded clay, and the heat-insulating layer 1 is made of aggregate fractions of 5-16 mm and a thickness of at least 20 mm, and the heat-accumulating layer 2 is made of fraction aggregate 3-10 mm and a thickness of at least 3.5 diameters of the thermal element 3.

The thermal element 3, laid in parallel rows with a pitch of 250-350 mm, is placed in the panel and is oriented either along or across the panel.

The distancers 6 are installed on an already prepared heat-insulating layer 1, and the thermal elements 3 with reinforcing meshes 4 and 5 installed on the distancers 6 are placed inside the heat-accumulating layer 2.

Ready thermal element 3 is not afraid of moisture, mechanical damage and is absolutely safe to use.

The heated floor, assembled from panels with used thermal elements 3, has the following advantages:

- it is reliable, because the heating thermal elements 3 withstand ultra-high mechanical loads, has high heat dissipation with low energy consumption, it is reliable due to the parallel connection of thermal elements 3 to the power network, namely, if one fails, the others continue to work;

- safe because the connection of the thermal elements 3 is equipped with hermetic waterproof couplings and has double insulation of the power cable, which increases mechanical protection and provides additional electrical safety;

- universal, as the panel is applicable both for heating and cooling rooms, porches, soil, and for all types of outdoor areas and is effective in all climatic zones, since it uses an anti-freezing coolant, refrigerant or electricity, it can be mounted under any road coating: screed, concrete, paving slabs, stone, asphalt, soil, etc., and the proposed design makes it possible to manufacture and use a panel of any size.

After mounting the walls, ceilings, roof and roof elements of the building, they proceed to the interior decoration, including installing a ventilation and heating system, whereby the floors and walls of the room are heated and the set temperature in the building is maintained.

The heating system of the building includes a heating device that maintains the set temperature in the building. To heat the floor and transfer heat to it, panels are used that are multilayer and modular and laid on the prepared base 9 with a waterproofing heat-reflecting layer 10 and connect them to the power supply system of the structure.

The use of expanded clay screening panel with a small dispersion in the size of the granules when laying the layers makes it possible to obtain the most uniform desired thermal and structural properties of the product. Bonding granules of encapsulated expanded clay together with each other in a monolithic composition occurs due to the active hydration of cement glue and thermal protection of the laid mass of the mixture. The set of strength of the stacked array does not require vibration, pressing and additional heat treatment and occurs at positive temperatures in the range of 15-25 degrees. To preserve the heat generated during hydration of the cement-adhesive composition, freshly laid lightweight concrete is covered with known heat-insulating materials.

High ecological purity of such panels is achieved through the use of environmentally friendly natural raw materials and low consumption of cement component, which leads to its high thermophysical, structural and operational properties, such as: low bulk density of 450-700 kg / m ³ , good sound insulation, good thermophysical properties , air and vapor permeability, uniform structural properties, high environmental cleanliness, high fire resistance and durability.

Using the proposed technical solution, it was possible to develop a multilayer modular panel for the manufacture of a warm heated floor, which is reliable in that the heating thermal elements withstand ultra-high mechanical loads and due to the parallel connection of the thermal elements to the power network; safe due to reliable insulation of the connection of thermal elements and double insulation of the power cable; and it is universal in application both for heating and for cooling rooms, porches, soil and all types of street areas, since it uses non-freezing coolant, refrigerant or electricity. As a result, the use of the proposed panel allowed us to create an energy-saving, useful for a person, comfortable, residential building.

Claims (4)

1. A panel for a warm floor, comprising a thermal element for heating and transferring heat to the floor, characterized in that it is laminated with heat-insulating and heat-accumulating layers of a homogeneous material, and the thermal element is made in the form of a corrugated thin-walled tube and placed in a heat-accumulating layer inside the heat the element is placed a heating element in the form of a wire or a spiral, and the thermal element is placed in the panel in the form of parallel rows with a pitch of 250-350 mm and is oriented either along or across the panel. 2. The panel according to claim 1, characterized in that the thermal element is placed in a heat-accumulating layer between two reinforcing meshes that are mounted on the spacers, and the heating element is made of heat-resistant and chemically resistant alloyed with rare-earth metals, and the free inner space of the thermal element is filled with finely ground a mixture of non-conductive electricity refractory, refractory materials. 3. The panel according to claim 1, characterized in that the heat-insulating layer and the heat-accumulating layer are made of encapsulated porous aggregate, at least expanded clay, and the heat-insulating layer is made of aggregate fractions of 5-16 mm and a thickness of at least 20 mm, and the heat-accumulating layer is made from aggregate fractions of 3-10 mm and a thickness of at least 30 mm, and at least 3.5 diameters of the thermal element. 4. The panel according to claim 1, characterized in that the corrugated thin-walled tube of the thermal element is mainly made of stainless steel, the heating element is made mainly of nichrome, and the inner space of the thermal element is filled with a ceramic mixture, mainly magnesium oxide MgO.

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