RU191998U1 - Multilayer facade panel - Google Patents

Abstract

The utility model relates to the construction and repair of buildings and structures for civil, industrial and agricultural purposes, in particular to the fencing systems of buildings with thermal insulation and decoration of external walls and facades, and can be used as a facade system for energy-efficient buildings. When implementing the claimed utility model the following technical result should be obtained: reduced energy consumption of the building; preservation of the thermotechnical properties of thermal insulation over the declared service life. The indicated technical result is solved due to the fact that the multilayer facade panel 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 composite material with a core made of mineral wool aggregate. The inventive utility model is aimed at creating a design of a multilayer facade panel that would be reliable, technologically advanced, could be manufactured in mass production and would help significantly reduce the energy consumption of the building.

Description

The utility model relates to the construction and repair of buildings and structures for civil, industrial and agricultural purposes, in particular to the fencing systems of buildings with thermal insulation and decoration of external walls and facades, and can be used as a facade system for energy-efficient buildings.

Known hinged ventilated facade [1], hinged ventilated facade [2], wall heat-insulating panel with a ventilated facade factory-ready "ROSLAV" and a support bracket for its installation [3].

The disadvantages of the known designs [1], [2], [3] is that they are complex and do not provide the preservation of the thermal characteristics of the heat-insulating layer during the declared service life. These designs [1], [2], [3] do not allow you to change the temperature in the ventilated gap.

The problem is that the known devices do not allow changing the air temperature in the air gap and ensure the preservation of the thermal characteristics of thermal insulation over the declared service life.

This problem is solved in that the multilayer facade panel contains two heat-insulating layers interconnected by bearing 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 composite material with a core of mineral wool aggregate. The inventive utility model is aimed at creating a design of a multilayer facade panel that would be reliable, technologically advanced, could be manufactured in mass production and would help significantly reduce the energy consumption of the building.

The technical result is achieved due to the improved design of the ventilated facade, consisting of multi-layer facade panels. The multilayer front panel consists of several layers: an external heat-insulating layer made of a composite material with a core of mineral wool aggregate; a system of bearing perforated profiles forming a closed ventilated air gap; a protective layer of moisture-proof cement slab, an internal heat-insulating layer and an inner protective layer of moisture-proof cement slab.

The protective layer between the insulation and the air gap allows you to maintain the thermal properties of the insulation during the declared service life, prevents loosening and moistening of the insulation. A closed ventilated air gap formed by two layers of thermal insulation allows to reduce the energy consumption of the building by regulating the temperature of the air flow in the gap.

The inner and outer protective layers of thermal insulation, which are moisture-resistant cement slabs, consisting of a core based on Portland cement and a light mineral aggregate, maintain thermal insulation over the declared service life, prevent its loosening, deformation and penetration of moisture into the panel, and also serve as a surface ready for interior decoration from the inside.

The outer heat-insulating layer of the panel is made composite with the core of non-combustible mineral wool insulation. The connection of the outer layer of the panel is leakproof due to the design of the groove-comb connection. This composite layer is separated from the main thermal insulation, protected by a cement slab, ventilated air gap. The fastening and connection of all layers in the level of the air gap is made by perforated profiles for unhindered air movement. This design of a multilayer facade panel forms a closed air gap between two layers of insulation. The tightness of the wall structure, made from these facade panels, allows the use of heated air in the gap to reduce the energy consumption of the building as a whole.

Multilayer facade panels are attached to the ends of the slabs floor by floor using a fastener in the form of an I-beam with ribs. In the grooves of the panel, made in the corners, a fastener is wound.

When implementing the claimed utility model, the following technical result can be obtained:

reduced energy consumption of the building;

preservation of thermotechnical properties of thermal insulation during the declared service life.

The utility model is illustrated by drawings 1-4. In FIG. 1 shows a general view of a utility model with a fastener 6. In FIG. 2 shows a fastening element 6 in the form of an I-beam with ribs, which is attached by a shelf to the end of the plate with anchors 7. In FIG. 3 presents a General view of a utility model with an indication of the layers: the inner protective layer 1, made of a moisture-resistant cement slab; thermal insulation layer 2; protective layer 3, also made of moisture-resistant cement slab; bearing perforated transverse and longitudinal profiles 4, forming a ventilated air gap; outer heat-insulating layer 5 made of composite material with a core of non-combustible mineral wool insulation. In the insulating layer 2, grooves 8 are arranged for connection with the fastening element 7. In FIG. 4 shows a multilayer facade panel in layers: a heat-insulating layer 2, the ends of which are framed by a perforated profile with a groove, lined with protective layers 1 and 3 on both sides; perforated profiles in two directions for organizing the air gap 4 and the outer heat-insulating layer 5.

There are several schemes for the effective use of a multilayer facade panel using heat exchangers 9 (Fig. 5 and 6, respectively):

1) Supply air enters the soil heat exchanger 9, thereby increasing its temperature to the positive temperature of the soil, from there it enters the air gap of the facade structure. Thus, the influence of external negative temperatures is compensated by a heated air stream that runs along the facade. Next, the supply air enters the supply and exhaust unit 10 with a filter, an air heater and a recuperator. From this installation, the air filtered and warmed there to the desired temperature enters the premises. Exhaust (exhaust) air also passes through a recuperator, in which it performs partial heating of the supply air, thereby reducing energy consumption (Fig. 5).

2) Supply air enters the soil heat exchanger 9, then enters the supply and exhaust unit 10, where it is heated, and from there it enters the premises. Exhaust air passing through the recuperator enters the air gap of the facade with a temperature approximately equal to the supply air temperature (Fig. 6).

Both of these schemes are possible and available for use due to the tight connection of the facade panels to each other, as well as the tight design of the window slope device. In the summer period, due to the use of these schemes, heat input decreases, as a result of which the required power of the air conditioning system decreases. This utility model can be used in regions with different climatic conditions, changing some parameters (thickness of the insulating and external composite layers).

The advantage of this utility model is to reduce the resource consumption and simplify the installation of the facade, reduce the energy consumption of the building through the use of the construction of a multilayer facade panel, as well as to increase the service life of thermal insulation.

Information sources:

1. Patent number 107534 IPC: E04B 1/00 2006.

2. Patent number 123801, IPC: E04B 1/00 2006.

3. Patent number 2448223, IPC: E04F 13/07 2006.

Claims (1)

A multilayer facade panel, characterized in that it contains two heat-insulating layers interconnected by supporting perforated profiles, forming a closed ventilated air gap, while moisture-resistant cement slabs are mounted to the inner heat-insulating layer of the panel, and the outer heat-insulating layer is made of composite material with a mineral wool core placeholder.

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