RU226101U1 - PREFABRICATED WARM WATER FLOOR PLATE - Google Patents

Abstract

The utility model relates to the field of thermal power engineering, in particular to floor-mounted heating devices for heating systems of buildings with liquid coolant, and can be used for installing heating systems without the use of heating radiators on any floors, including in wooden, frame buildings, both residential and and non-residential premises for any purpose. The STVP slab is made from a gypsum-based mixture with the addition of polymer additives and reinforcing material; the optimal balance of strength, flexibility and thermal properties makes it possible to combine the function of a heat-distributing and load-bearing layer of a heating device built into the floor. At the same time, the STVP slab has a weight that allows it to be used, including in wooden, frame buildings, on any floors in any premises. The thermal properties of the STVP slab make it possible to use it as a heat-distributing and load-bearing layer of a heating device built into the floor, including in rooms on the first floor and rooms under which there is an unheated basement. The STVP slab is made in the form of a monolithic rectangular slab from a gypsum-based mixture with the addition of polymer additives and reinforcing material. Cylindrical protrusions are evenly distributed over the entire surface of the STV plate, with a distance between the nearest protrusions taking into account the thermal expansion of the pipe and providing friction at the point of contact of the pipe with the protrusions, which allows you to securely fix the pipe in the channel without additional fasteners. The protrusions located in the corners of the slab are cut in a vertical plane and have the shape of a quarter of a cylinder. The protrusions located along the edge of the slab are cut in a vertical plane and have the shape of half a cylinder. The arrangement of the protrusions along the surface of the slab creates its axial symmetry, ensuring versatility of laying on any side. Fixation of the joining of STVP slabs to each other is ensured by the own weight of the slabs. The STVP slab can be used to install a heating device built into the floor, both “dry” and “wet” methods.

Description

The utility model relates to the field of thermal power engineering, in particular to floor-mounted heating devices for heating systems of buildings with liquid coolant, and can be used for installing heating systems without the use of heating radiators on any floors, including in wooden, frame buildings, both residential and and non-residential premises for any purpose.

A heat exchanger unit is known [Patent FR No. 2790819, IPC F24D 3/14, F28F 1/12, F28F 1/22, publ. 09.15.2000], intended for use on suspended floors or embedded in the ground, contains a piping circuit installed between the base and the floor covering.” The heat exchanger assembly contains a base on which pipes are installed to transport the heated liquid. The pipes are attached to the base with a grating and embedded in the floor covering layer. The heat exchange units can be connected in such a way that a continuous circuit can be formed. The fastenings allow each heat exchanger unit to be mounted on a ground or floor suspension.

The disadvantage of the proposed technical solution is the high labor intensity of the process of attaching the pipe to a metal mesh; the ability to use the material in wooden/frame houses is limited due to the large weight due to the need to use a cement screed as a heat-distributing layer. It is used as a load-bearing layer and is not a heat-distributing layer.

A known stove for a heating system [Patent RU No. 169454, IPC F24D 3/00, publ. 03.17.2017], containing a base, on the working side of which a coating of high-strength polymer film material is applied, and there are rows of bosses made of high-strength polymer film material; Moreover, on one side of the slab, the outer row of bosses is made smaller than the rest, the upper part of which is made in the form of a multifaceted element with protruding corners relative to the body of the boss, beveled from above for fixing the tubes to the base, while the rows of bosses form channels with a U-shaped cross-section for laying pipes.

The disadvantage of the described analogue is the non-universal arrangement of grooves for placing heating elements, the difficulty in connecting the slabs that form the surface of the heated floor, the low thermal conductivity of the manufacturing material, which limits the possibility of using a heating system without radiators in the rooms of the first floor and the rooms under which it is located. unheated basement. It is used as a load-bearing layer and is not a heat-distributing layer.

A known panel for a warm water floor [Patent RU No. 202342, IPC F24D 3/12, publ. 02.12.2021], containing a base made of extruded polystyrene foam, on the working surface of which there are rows of supporting protrusions, the cross section of which has the shape of an ellipse, and on the surface areas located between four adjacent supporting protrusions, groups of four protrusions are made, arranged in this way , which form additional channels for laying tubular elements of the water floor. The protrusions in the mentioned groups have the shape of a straight triangular prism with a right triangle at the base. The protrusions in the group are oriented at right angles to the center of the group and are equidistant from each other and from the cylindrical protrusions adjacent to them.

The disadvantage of the described analogue is the low thermal conductivity of the manufacturing material, which limits the possibility of using a heating system without radiators in rooms on the first floor and in rooms under which an unheated basement is located. It is used as a load-bearing layer and is not a heat-distributing layer.

Known mats are KNAUF Therm® Warm floor PRO, which are molded mats made of polystyrene foam coated with rigid PS film with a pipe laying pitch of 50 mm and are used as a load-bearing layer. To construct a heat-distributing layer, a screed made of a cement-sand mixture is used (see https://knauf-penoplast.ru/wp-content/uploads/2021/03/brochure-TP-2020-goda.pdf).

The disadvantage of the described analogue is the limited possibility of using the material in wooden/frame houses due to the large weight due to the need to use a cement screed as a heat-distributing layer. It is used as a load-bearing layer and is not a heat-distributing layer.

Known KNAUF Therm® Warm floor mats, which are a molded polystyrene foam mat with a pipe laying pitch of 100 mm, are used as a load-bearing layer. To install a heat distribution layer, a screed made of a cement-sand mixture or KNAUF Therm® heat distribution plates made of galvanized steel sheet of omega shape are used (see https://knauf-penoplast.ru/wp-content/uploads/2021/03/brochure- TP-2020.pdf.

The disadvantage of the described analogue is the need to use heat distribution plates or a screed made of a cement-sand mixture to install a heat distribution layer. It is used as a load-bearing layer and is not a heat-distributing layer.

The closest material taken as a prototype is a panel for a warm water floor [Patent RU No. 201812, IPC F24D 3/00, publ. 01/13/2021], containing a rectangular base made of extruded polystyrene foam, the width of which is 580 mm, the length is 1180 mm, on the working surface of which there are rows of supporting protrusions, and between the protrusions there are channels for laying pipes, 13 mm wide and depth, according to essentially equal to the diameter of the pipe, and on the surface areas located between four adjacent supporting protrusions, groups of four protrusions are made, arranged in such a way that they form additional channels for laying tubular elements of the water floor.

The disadvantage of the proposed technical solution is the low thermal conductivity of the manufacturing material, which limits the possibility of using a panel for a warm water floor to install a heating system without radiators in rooms on the first floor and in rooms under which an unheated basement is located. It is used as a load-bearing layer and is not a heat-distributing layer.

The objective of the claimed utility model is to create slabs for the installation of heating systems with a liquid coolant built into the floor, without the use of radiators, which simultaneously perform the function of a heat-distributing and load-bearing layer of a heating device built into the floor, while having a weight that allows the slabs to be used, including in wooden, frame buildings, in any premises on any floors, including in the premises of the first floor and the premises under which there is an unheated basement, without taking additional measures for thermal insulation and strengthening the structure.

The technical result is to increase speed and ensure ease of installation of the slab base due to the weight of the slab and the absence of structural fasteners.

The technical result is achieved due to the fact that the prefabricated heated water floor slab is made of gypsum, polymer additives and reinforcing material, monolithic and contains a rectangular base, on the working surface of which there are rows of support protrusions, between which there are channels for laying pipes. Moreover, the protrusions are evenly distributed over the entire surface of the base.

The protrusions are made of a cylindrical shape and are located evenly over the surface of the slab so that the distance between the nearest protrusions is the same and takes into account the thermal expansion of the pipe, which allows you to fix the pipe without additional fasteners. The protrusions located in the corners of the slab are cut in a vertical plane and have the shape of a quarter of a cylinder, and the protrusions located at the edges of the slab are cut in a vertical plane and have the shape of a half cylinder.

In FIG. 1 shows the slab in a vertical position.

In FIG. Figure 2 shows the slab in a horizontal position.

A rectangular monolithic slab is made of a gypsum-based mixture with the addition of polymer additives and reinforcing material with cylindrical protrusions evenly distributed over the entire surface, with a distance between the nearest protrusions taking into account the thermal expansion of the pipe and providing friction at the point of contact of the pipe with the protrusions, which allows for reliable fixation pipe in the channel without additional fastenings.

The protrusions located in the corners of the slab are cut in a vertical plane and have the shape of a quarter of a cylinder. The protrusions located along the edges of the slab are cut in a vertical plane and have the shape of half a cylinder. The arrangement of the protrusions along the surface of the slab creates its axial symmetry, ensuring versatility of laying on any side.

These features are essential and are interrelated to form a stable set of essential features sufficient to obtain the required technical result.

Gypsum is a mineral from the sulfate class, the composition is calcium sulfate dihydrate with the chemical formula CaSO4⋅2H2O. The fibrous variety of gypsum is called selenite, and the granular variety is called alabaster.

The use of gypsum as part of the slab manufacturing material provides the necessary thermal properties for use as a heat-distributing layer due to effective thermal conductivity, weight, strength for use as a load-bearing layer and effective pipe laying.

Polymer additives (modifiers) are compositions based on polyorganosiloxane. They are used as a component of highly filled polymer compositions and improve the properties of the compositions.

Polymer additives can be used, for example: polyester resins, rubber resins, acrylic resins.

The use of polymer additives in the composition of the slab material ensures the flexibility and water resistance of the slab.

Reinforcing material is a material introduced into the binder to enhance the physical and mechanical properties and give the composition the qualities of a structural material.

Reinforcing material can be used, for example: polypropylene fiber, fiberglass fiber, basalt fiber.

The reinforcing material serves as a compensator for tensile forces.

The claimed slabs have strength and thermal properties that allow them to be used simultaneously as a heat-distributing and load-bearing layer of a heating device built into the floor.

Making a slab from a gypsum-based mixture with the addition of polymer additives and reinforcing material provides an optimal balance of flexibility, weight, and thermal properties.

Due to the execution of the protrusions from the claimed mixture, their cylindrical shape has sufficient rigidity for reliable fixation of the pipe due to frictional force.

Let's consider an example of the manufacture and use of a slab.

Fiberglass fiber and acrylic resin are added to the plaster, everything is mixed until smooth.

The resulting mixture is poured into a mold. After hardening, the resulting slab is removed from the mold.

Polyester resin and rubber resins can be used as a polymer additive, and polypropylene fiber and basalt fiber can be used as a reinforcing material. When using any polymer additives and reinforcing material, a technical result is achieved.

Installation of heated floors using slabs is carried out as follows. On a prepared base, for example, a wooden floor, the slabs are laid joint to joint with any edge. If it is necessary to install slabs in a room with irregular geometry, the slabs are cut with any cutting tool.

The heating pipe is laid in the channels between the cylindrical protrusions using the necessary method of laying out the loops. Next, a final floor covering, such as tiles, is laid on the mounted surface. Before laying laminate or parquet, a plasterboard sheet must be laid.

The declared slab can be installed at any temperature (due to the absence of “wet” processes). At the same time, the installation process is low noise and fast. It is possible to carry out the work in stages (interrupting the installation process at any stage will not affect the quality of the mounted surface). The geometry of the room can be any.

Due to the fact that the slab is made from a gypsum-based mixture with the addition of polymer additives and reinforcing material, an optimal ratio of flexibility, weight, and thermal properties is achieved, ensuring the combination of a heat-distributing and load-bearing layer in one structure.

The weight of the slab is comparable to the weight of a gypsum fiber sheet due to the presence of polymer additives in the manufacturing material, which makes it possible to install heating systems without the use of radiators on any floor, including in wooden and frame buildings.

The slab has effective thermal conductivity due to the gypsum content in the manufacturing material, which ensures effective uniform heating of the room without the use of radiators.

Due to the gypsum content in the manufacturing material, the slab has effective thermal properties that provide effective thermal conductivity, which allows saving energy to maintain the temperature of the coolant and high thermal inertia, which allows slowing down the cooling process of the floor surface in the event of cooling of the coolant.

The slab has sufficient weight, strength and flexibility due to the content of gypsum, polymer additives and reinforcing material in the composition of the manufacturing material, which ensures high speed and ease of installation of the slab base. In addition, installation speed is ensured due to the absence of structural fasteners.

The main material used for making the slab is gypsum, due to which the cylindrical protrusions located over the entire surface of the slab have sufficient strength and friction coefficient for reliable fixation of the pipe without the use of additional fasteners.

Water resistance and flexibility are ensured by the content of polymer additives. The reinforcing material included in the manufacturing material provides compensation for tensile forces.

Due to the gypsum content in the manufacturing material, the slab has sufficient weight and thermal conductivity, in addition, it is fire-resistant and environmentally friendly.

Claims (3)

1. A prefabricated heated water floor slab, characterized in that it contains a base on the working surface of which there are rows of supporting protrusions, between which there are channels for laying pipes, wherein the slab is made of gypsum, polymer additives and reinforcing material, and the protrusions are evenly distributed over the entire surface of the base. 2. The prefabricated heated water floor slab according to claim 1, characterized in that the protrusions are cylindrical in shape and are located evenly over the surface of the slab so that the distance between the nearest protrusions is the same and takes into account the thermal expansion of the pipe, which allows you to fix the pipe without additional fasteners. 3. Prefabricated heated water floor slab according to any one of paragraphs. 1, 2, characterized in that the protrusions located in the corners of the slab are cut in a vertical plane and have the shape of a quarter of a cylinder, and the protrusions located at the edges of the slab are cut in a vertical plane and have the shape of a half cylinder.