RU79604U1 - DOOR LEAF - Google Patents

Abstract

The utility model relates to the field of construction, namely to door structures. The utility model will increase the stiffness properties of the door leaf, give a certain fire resistance, strengthen the anti-corrosion and heat, soundproof properties of the door leaf. The present utility model is based on the task of creating a door leaf whose structural design would primarily increase the stiffness of the door, give the product greater corrosion resistance, significantly reduce the risk of ignition of door components, and increase heat and sound insulation properties. The problem is solved by creating a door leaf containing at least one outer (facing the external environment) layer of artificial or natural stone, followed by a composite layer consisting of polymer resins and a layer of aluminum honeycombs, which, in turn, consists of two aluminum plates, between which are laid elements of a similar metal, in the form of honeycombs.

Description

The utility model relates to the field of construction, namely to door structures.

The utility model will increase the stiffness of the door leaf, impart a certain fire resistance, enhance the anti-corrosion and heat, sound insulation properties of the door leaf, increase the resistance of the door leaf to unauthorized access.

As the closest analogue, a method for manufacturing a door leaf was adopted in accordance with which a layer of rigid foam foams and sticks to at least one surface plate of natural or artificial stone or is applied in the form of foam on it, after which this first surface plate is then is cut off or ground (calibrated) to a minimum thickness and a fiberglass mat is placed between the first surface plate, consisting of natural or artificial stone, and the inner layer and a polymer or melanin-resin plate, wherein the fiberglass mat or polymer or melanin-resin plate is glued to the surface of the first surface plate facing the inner layer, and the first surface plate is then glued on top of this fiberglass mat or polymer or melanin-resin plate with an inner layer or foamed on them. (RU 2004116912). The above method allows the manufactured product to have high decorative and anti-corrosion properties, but a door containing fiberglass and foam is extremely resistant to fire and, in general, the design of this door leaf does not have the necessary rigidity to be installed as an external door, and Exterior doors, in particular, need reliable protection against corrosive substances.

The present utility model is based on the task of creating a door leaf whose structural design would increase primarily the stiffness of the door, give the product greater corrosion resistance, significantly reduce the risk of fire of door components, increase heat and sound insulation properties, and increase protection against unauthorized access.

The problem is solved by creating a door leaf containing at least one outer (facing the external environment) layer of artificial or natural stone, followed by a composite layer consisting of polymer

resins and a layer of aluminum honeycombs, which, in turn, consists of two aluminum plates, between which are laid elements of a similar metal, in the form of honeycombs.

The above-described implementation of the outer layer of artificial or natural stone gives the door leaf anti-corrosion properties and prevents mechanical damage. The presence of such a layer does not allow the fire to spread when it occurs, which causes a certain fire resistance of the door. In addition, this layer increases the door's resistance to criminal access by heating with a gas-flame cutter, because when heated, the stone, unlike a metal door, does not melt, but transfers heat through a polymer layer to a layer of aluminum honeycombs, which, in turn, dissipates excess heat. The layer can be made either on one side, or on both sides of the door leaf, or on all sides. A color and texture combination of stone elements is possible, which gives the door leaf high ergonomic properties.

The implementation of the composite layer consisting of polymer resins provides cushioning stability. The composite layer may also be on one or more sides of the door leaf.

The presence of an aluminum honeycomb block gives the necessary rigidity to the entire structure. In addition, the honeycomb, in view of the presence of air between the structural elements, provides thermal insulation properties, and the metal plates between which the honeycombs are enclosed, damping the vibration, determine the soundproofing properties of the stiffener. The use of aluminum in this case seems appropriate, since the indicated metal has anticorrosive properties and does not have a large weight.

It is also advisable to use one layer, but more than one layer of aluminum honeycombs can be used.

All layers are bonded to each other using any available method that meets the necessary requirements for the degree of connection of the door leaf elements to each other.

For a better understanding of the utility model, a specific embodiment is provided below with reference to the attached drawing, in which FIG. 1 depicts a layered arrangement of door leaf elements.

The door leaf 1 contains layers of natural or artificial stone 2, composite layers 3, a layer of aluminum honeycombs 4, consisting of plates 5 and elements making up the cells 6.

Claims (1)

A door leaf characterized by the presence of at least one layer of natural or artificial stone, one or more composite or adhesive layers, one or more layers of aluminum plates with aluminum elements between them in the form of honeycombs.