RU205372U1 - Energy efficient façade panel with air mesh - Google Patents

Abstract

The utility model relates to the field of industrial and civil construction, in particular to building fencing systems, and can be used in the construction and construction of energy-efficient buildings, as well as in the reconstruction of previously operated structures to give them aesthetic qualities and increase the degree of thermal insulation and protection from external atmospheric influences The main goal of this constructive proposal is to provide thermal protection of the building, increase the active thermal resistance and reduce heat loss, increase the energy efficiency of buildings and structures under construction and in operation due to an effective facade structure without the use of heat-insulating material (insulation). that in order to increase the active thermal resistance and reduce heat loss, the cavity (air gap) is made in the form of sealed cells, the dimensions of which are chosen so as to block free convective flows inside each cell to create a stationary space filled with air (or gas - argon, xenon, krypton, sulfur hexafluoride) inside each cell. , could be mass-produced and would help significantly reduce building energy costs.

Description

The utility model relates to the field of industrial and civil construction, in particular to building fencing systems, and can be used in the construction and construction of energy-efficient buildings, as well as in the reconstruction of previously operated structures, to give them aesthetic qualities and increase the degree of thermal insulation and protection from external atmospheric impacts.

The main goal of this constructive proposal is to provide thermal protection of the building, increase the active thermal resistance and reduce heat loss, increase the energy efficiency of buildings and structures under construction and in operation due to an effective facade structure without the use of heat-insulating material (insulation).

At the moment, almost all enclosing structures of buildings and structures are multilayer, where the thermal protection of the building is provided by a heat-insulating layer - insulation. There are curtain-sided ventilated facade systems, multi-layer building envelopes and panels with a thermal insulation layer, facades with buffer zones, as well as flat facade panels and cassettes.

A hinged ventilated facade made of box-shaped panels (RU 2 320 834 C1) is known from the prior art, which includes a support profile fixed on the surface to be clad and a set of mounting elements fixed on it for fixing box panels, characterized in that the upper and lower walls of the box panels are made holes, near which fasteners are fixed, and the mounting elements are equipped with elastically deformable fixing legs located outside the plane of the support profile, while the shape and dimensions of the holes, fastening and installation elements, fixing legs, as well as their relative position are selected from the condition of ensuring the possibility of deepening the fixing legs through the holes into the cavity of the panels during their installation and their elastic interaction with the fastening elements of the panels at their final position, provided that the side walls of the box panels are supported on the support profile.

The main disadvantage of this solution is that it is aimed more at improving the appearance of the facade, simplifying installation and saving fasteners, while this solution does not provide an adequate level of thermal protection of the building and can be used in those regions where there is no significant difference in indoor temperatures. and the environment.

An energy-saving facade panel (RU 172633 U1) is known, an energy-saving panel consisting of at least one plate of heat-insulating material based on basalt fiber with a thickness of at least 40 mm, placed in two supporting metal profiles, and the metal profiles are C-shaped, not thick less than 1.3 mm and are fixedly connected to the slab by pressing, and the slabs are interconnected by non-metallic facade fasteners.

The disadvantage of this design is that to ensure heat-shielding properties, it is necessary to have a heat-insulating material, it does not fully use the capabilities of air as a heat-insulating material and requires a heat-insulating layer, there is a potential for a significant increase in active thermal resistance due to volumes containing immobile air.

The closest technical solution to the claimed one is a multilayer facade panel (RU 191 998 U1), which contains two heat-insulating layers, interconnected by supporting perforated profiles, forming a closed ventilated air gap; at the same time, moisture-resistant cement slabs are mounted to the inner heat-insulating layer of the panel, and the outer heat-insulating layer is made of a composite material with a mineral wool core. The disadvantage of this design is that it does not fully use the capabilities of air as a heat-insulating material and requires a heat-insulating layer; there is a potential for a significant increase in active thermal resistance due to volumes containing immobile air. The disadvantage of the known described panel can also be attributed to the weight of the panel, which limits the scope of use of this structure to low-rise buildings and forces the use of massive fasteners.

In the proposed device for increasing the active thermal resistance and reducing heat loss, the air gap is made in the form of sealed cells, the dimensions of which are chosen so as to block free convective flows inside each cell in order to create a stationary air space inside each cell.

At the moment, almost all enclosing structures of buildings and structures are multilayer, where the thermal protection of the building is provided by a heat-insulating layer - insulation. There are curtain-sided ventilated facade systems, multi-layer building envelopes and panels with a thermal insulation layer, facades with buffer zones, as well as flat facade panels and cassettes.

The technical result will be a significant increase in active thermal resistance and a decrease in the mass of the panel.

The technical result is achieved by the fact that the structure uses volumes containing still air (or inert gas - argon, xenon, krypton, sulfur hexafluoride) with low thermal conductivity.

The essence of the utility model is illustrated by drawings.

Figure 1 shows an energy-efficient facade panel with an air cellular cavity, in which, in order to increase the active thermal resistance and reduce heat loss, the air gap is made in the form of sealed cells, the dimensions of which are chosen so as to block free-convective flows inside each cell in order to create a stationary airspace within each cell. The figure shows the following elements: 1 - wall, 2 - composite panel, 3 - spherical elements with stationary air (or inert gas - argon, xenon, krypton, sulfur hexafluoride), 4 - polypropylene mesh; 5-fastener; 6– thermal break.

Figure 2 presents a three-dimensional view of an energy efficient facade panel with an air cellular cavity. The figure shows the following elements: 2 - composite panel; 3 - spherical elements with stationary air (or inert gas - argon, xenon, krypton, sulfur hexafluoride), 4 - polypropylene mesh; 5-fastener.

Figure 3 shows fasteners.

Figure 4 shows the fastening element.

The panel is attached to the main supporting element - a column, floor or wall (1) using fasteners (5) that hold the panel in four places and which are installed in ceilings, walls and columns, in a vertical gap, depending on the size of the proposed panel and structural building solutions. The distance between the fasteners can vary depending on the design requirement. The panel is a box-shaped cladding element. The outer face, as well as the end faces that form the length of the panel, are made of a composite panel (2). 3 edges (inner, adjacent to the wall and 2 end, lower and upper, forming the thickness of the panel), are polypropylene mesh (4). The panel cavity is an air cavity filled with spherical elements (cells) (3) with a fixed volume of air (or inert gas - argon, xenon, krypton, sulfur hexafluoride) made of an airtight polymer material. A thermal break (6) is installed between the supporting base and the fastening elements to avoid the formation of cold bridges and minimize their negative impact on the thermal properties of the enclosing structures.

Mesh edges avoid waterlogging of the wall structure and the formation of a dew point at the border of the wall and the panel. The size of the spherical elements is determined by carrying out a heat engineering calculation, depending on the type of building and the corresponding climatic zone. The outer edge, as well as the end faces that form the length of the panel, are made of a composite panel (2 sheets of aluminum and filling between the sheets).

The inner box-shaped cavity is an air gap in the form of sealed cells, the dimensions of which are chosen so as to block free convective flows inside each cell in order to create a stationary space filled with air (or gas - argon, xenon, krypton, sulfur hexafluoride) inside each cells.

Thus, the main technical result is achieved - an increase in active thermal resistance and a decrease in heat loss, ensuring thermal protection of the building, increasing the energy efficiency of buildings and structures under construction and in operation due to an effective facade structure without the use of heat-insulating material (insulation).

In addition to thermal protection and protection against waterlogging of the structure, such a panel is very lightweight, which reduces the load on the supporting structures of buildings and structures, thanks to which it can be used for the construction of buildings and structures of any height. The use of the panel to obtain additional savings due to the rejection of an additional heat-insulating layer, works on its fastening and related components and transport costs.

Claims (1)

A box-shaped facade panel with a closed air cavity, characterized in that the outer edge forming it, as well as the end edges forming the panel length, are made of composite panels, and the inner, lower and upper edges are made of polypropylene mesh, while the cavity formed edges, filled with sealed spherical elements made of airtight polymer material, filled with air.

Images