RU162379U1 - HEAT AND SOUND INSULATION PANEL - Google Patents

Abstract

1. A heat and sound insulating panel comprising at least three layers connected in series at the molecular level, each of which contains at least one airtight cavity with a vacuum inside, and the airtight cavities of adjacent layers are asymmetrical relative to each other, thus that when drawing the shortest straight line from the plane of the inner extreme layer, with the exception of its perimeter, to the plane of the outer extreme layer, the straight line will go through at least one tiled cavity with vacuum. 2. A heat and sound insulating panel according to claim 1, characterized in that the sealed cavity is made in the form of a sealed cell. 3. A heat and sound insulating panel according to claim 2, characterized in that the sealed cell is made in the form of a prism with symmetrical bases in the form of trapezoid. 4. A heat and sound insulating panel according to claim 1, characterized in that each layer is made of a polymeric material. The heat and sound insulation panel according to claim 1, characterized in that each layer is made of foam. 6. The heat and sound insulating panel according to claim 1, characterized in that the sealed cavity is made of plastic. 7. A heat and sound insulating panel according to claim 1, characterized in that the sealed cavity is made of metal. The heat and sound insulating panel according to claim 1, characterized in that the sealed cavity is made of a glass cavity with metal spraying. A heat and sound insulating panel according to claim 1, characterized in that the last extreme layer is covered with a heat insulating material. 10. The heat and sound insulation panel according to claim 9, characterized in that the heat insulation material is made of foil. 11. Sound and sound insulation

Description

The technical field to which the utility model relates.

The utility model relates to heat and sound insulating panels used in industrial and civil engineering.

State of the art

Known heat and sound insulation panel (RU 144642 U1, publ. 08.27.2014), including surface mirror-made layers with the formation between them along the perimeter of adjacent spike and groove, offset diagonally relative to the outer surfaces of the layers, and symmetrically made honeycomb cells in the form of regular hexagonal recesses on the inner surfaces of the layers, and the spike and groove are formed by mirrored parts on the inner surfaces of the layers in the form of ledges monolithic with the surface layers.

The disadvantages of this analogue are poor thermal and sound insulation of the panel itself, since the cells are symmetrically relative to each other. It should be noted that these honeycomb cells of each individual layer are not tight (since only two or more layers contain cavities together) and do not contain vacuum, and the presence of a spike and groove connection between the layers also affects the insufficient heat and sound insulation properties of the panel.

Utility Model Disclosure

The technical result consists in increasing the heat and sound insulating properties due to airtight cavities with vacuum inside each layer, asymmetric arrangement of airtight cavities with vacuum of each layer relative to airtight cavities with vacuum of an adjacent (or neighboring) layer, so that when passing cold air or sound vibrations they will have to make a winding path along the partitions, since the sealed cavities of adjacent (or neighboring) layers are overlapped relative to each other. In addition, this result is achieved by connecting the layers together at the molecular level.

A heat and sound insulating panel comprising at least three layers connected in series at the molecular level, each of which contains at least one airtight cavity with a vacuum inside, and the airtight cavities of adjacent (or adjacent) layers are asymmetrical relative to each other, so that when drawing the shortest straight line from the plane of the inner extreme layer, with the exception of its perimeter, to the plane of the outer extreme layer, the straight line will pass through at least m Here, one sealed cavity with vacuum.

According to a utility model, the sealed cavity is made in the form of a sealed cell.

According to a utility model, a sealed cell is made in the form of a prism with symmetrical bases in the form of trapezoid.

According to a utility model, each layer is made of a polymeric material.

According to a utility model, each layer is made of foam. According to a utility model, the sealed cavity is made of plastic.

According to a utility model, the sealed cavity is made of metal.

According to a utility model, the sealed cavity is made of a glass cavity with metal spraying.

According to a utility model, the last extreme layer is coated with a heat insulating material.

According to a utility model, the insulating material is made of foil.

According to a utility model, the insulating material is made of felt.

According to a utility model, each layer is made of a waterproof material.

According to a utility model, each layer is made of durable elastic material.

According to a utility model, the insulating material is adhered to the last extreme layer.

According to a utility model, a panel comprises grooves along its edge that are configured to be studded with at least one additional panel.

Brief Description of the Drawings

The essence of the utility model is illustrated: FIG. 1, which shows the first layer of the claimed panel with sealed cavities in longitudinal section; FIG. 2, which shows the second layer of the claimed panel with a sealed cavity in longitudinal section; FIG. 3, which shows the first layer of the claimed panel with sealed cavities in longitudinal section and with the projection of the sealed cavity of the second layer onto it, when the layers are connected to each other.

Utility Model Implementation

In FIG. 3 shows the first layer 1 of the claimed panel with sealed cavities 2 (see also Fig. 1) in longitudinal section, the sealed cavity 3 of an adjacent (adjacent) second layer 4 (see Fig. 2) is located asymmetrically relative to the sealed cavities 2 of the first layer 1 and the third layer can be performed, for example, similarly to the first layer or with any other asymmetric arrangement of its sealed cavities relative to the sealed cavity 3 of the second layer. The specified asymmetric arrangement of the sealed cavities of adjacent (or neighboring) layers relative to each other is such that when drawing the shortest straight line from the plane of the inner extreme layer with the exception of its perimeter to the plane of the outer extreme layer, the straight line will go through at least one airtight cavity with vacuum, i.e. in fact, the cavities of adjacent (neighboring) layers relative to each other will be located as if overlapping.

Thus, such a panel design has more heat and sound insulating properties, since the sealed cavities of the layers with vacuum cover the entire area of the panel.

In addition, in a particular embodiment, the panel may contain along its edge, for example around the entire perimeter or partially along one, two or three sides, grooves made with the possibility of a spike connection with at least one additional panel made with mating grooves.

It should be noted that all cavities are isolated from each other (do not have communication channels), and all layers can be made heat-insulating in a particular embodiment. In addition, the layers are interconnected without the use of glue and other binders.

In another embodiment of the claimed utility model, all panel elements are made of one (uniform) material, with the exception of the heat-insulating material, which can cover the last (extreme) layer, and the fact that the grating material inside each layer and the fixing layer can have a higher temperature melting than the material of the interlayer and parallel to the outer walls of each layer.

Moreover, in the above particular embodiment of the utility model, the last extreme layer, which is coated with a heat-insulating material, will also additionally affect the claimed technical result, which consists in increasing the heat and sound insulating properties of the panel.

The panel can be made without a separate element - a honeycomb core. The design is made without cores, fittings and other supporting elements. The panel is made of waterproof material. The design of the panel is made without endings.

The design of the panel has significant flexibility without violating the structure and properties, due to the use of layers of durable flexible material.

The design of the panel is made without gaskets between the layers.

The design provides for the possibility of attaching the panel to the surface using fasteners, requiring the creation of through holes in the panel, without significant loss of its properties.

The design provides for the possibility of applying any decorative coating to the panel.

The design of the panel does not include an element: check valve.

Instead of hollow channels, the panel contains cells isolated from each other.

The design of the panel does not include the use of evacuated nanostructured powder.

The design of the panel can be made of translucent (translucent) material.

The design of the panel does not include the use of foamed filler.

Claims (15)

1. A heat and sound insulating panel comprising at least three layers connected in series at the molecular level, each of which contains at least one airtight cavity with a vacuum inside, and the airtight cavities of adjacent layers are asymmetrical relative to each other, thus that when drawing the shortest straight line from the plane of the inner extreme layer, with the exception of its perimeter, to the plane of the outer extreme layer, the straight line will go through at least one meticulous cavity with vacuum. 2. The heat and sound insulation panel according to claim 1, characterized in that the sealed cavity is made in the form of a sealed cell. 3. The heat and sound insulating panel according to claim 2, characterized in that the sealed cell is made in the form of a prism with symmetrical bases in the form of trapezoids. 4. The heat and sound insulation panel according to claim 1, characterized in that each layer is made of a polymeric material. 5. Heat and sound insulation panel according to claim 1, characterized in that each layer is made of foam. 6. The heat and sound insulation panel according to claim 1, characterized in that the sealed cavity is made of plastic. 7. The heat and sound insulation panel according to claim 1, characterized in that the sealed cavity is made of metal. 8. The heat and sound insulation panel according to claim 1, characterized in that the sealed cavity is made of a glass cavity with a metal coating. 9. The heat and sound insulation panel according to claim 1, characterized in that the last extreme layer is covered with heat insulation material. 10. Heat and sound insulation panel according to claim 9, characterized in that the heat-insulating material is made of foil. 11. Heat and sound insulation panel according to claim 9, characterized in that the heat-insulating material is made of felt. 12. The heat and sound insulation panel according to claim 1, characterized in that each layer is made of a waterproof material. 13. The heat and sound insulating panel according to claim 1, characterized in that each layer is made of durable elastic material. 14. Heat and sound insulation panel according to claim 9, characterized in that the heat-insulating material is glued to the last extreme layer. 15. The heat and sound insulating panel according to claim 1, characterized in that the panel comprises grooves along its edge that are configured to be studded with at least one additional panel.

Images