RU189434U1 - PANEL FRONT HEATING - Google Patents

Abstract

The utility model relates to the field of construction, namely to the combined construction panels, and can be used for insulation, external protection and decorative finishing of the facades of buildings, including for the manufacture of unventilated facades. operation by increasing the resistance of the panel to the adverse effects of the environment. The facade insulation panel contains an outer layer of fibrous cement and an inner layer teplitelya. The layers are interconnected by the “dovetail” method. At one end, the outer layer is made in a stepped form, the upper step being made with a protrusion turned upwards, and at another opposite end, the outer layer is also made with a protrusion. The profile of the outer layer is made with the formation of a mechanical locking system with the possibility of engagement when mounting adjacent panels with each other. 3 il.

Description

The invention relates to the field of construction, in particular to the combined construction panels, and can be used for insulation, external protection and decorative finishing of the facades of buildings, including the manufacture of non-ventilated facades.

The prior art known combined construction panel, the edges of which on the sides form locking elements. The heat-insulating part of polyurethane foam and the decorative facing part of the clinker tile are fastened together (patent RU 2468165, IPC E04F 13/08, publ. 04/27/2010). A disadvantage of the known device is the fastening of the panel through and the need to grind the joints between the panels.

The prior art multilayer panel containing a base layer of reinforced concrete, a heat-insulating layer and a waterproofing layer (patent RU 18179 "Multi-layer heat-insulating panel", IPC E04C 2/296, publ. 27.05.2001). The heat-insulating layer is made of fibro-gas-bitumen-concrete reinforced with synthetic fiber. The disadvantages of this panel are the large weight of the product, the absence of interfaces and the possibility of choosing the type of insulation. Installation of plates is carried out joint to the joint, therefore, when moisture gets between the joints of the panels, cold bridges are formed, which will lead to a decrease in the service life. Installation of such a panel on the facade is difficult because of the mass, so the most appropriate use of the application - for insulating flat roofs.

Known facing panel, which contains the outer layers of sheet building material, while the outer outer layer is made of hydrophobic fiber cement plate, and another layer is made of waterproof gypsum-cement fiber board (patent RU 141333 "Facing panel", IPC E04C 2/296, publ 05.27.2014, the prototype). The inner heat-insulating layer consists of two or more layers made of extruded or extruded polystyrene foam of equal thickness, placed between the outer layers and displaced relative to each other in two mutually perpendicular directions by an equal amount. The outer layers of the cladding panel are also shifted in two mutually perpendicular directions by the same amount, forming a spike-groove form together with the inner heat-insulating layers. The outer layers and the inner layers are fixed relative to each other using adhesive bonding. The disadvantage of this technical solution is the fixation of the outer and inner layers using adhesive bonding and the use of the locking connection of tongue and groove exclusively for the insulation, but not for the protective layer of fiber cement. This increases the possibility of moisture to the heater and the formation of cold bridges. There is also no solution for the method of mounting the panel on the facade, ensuring the absence of a through hole.

The technical challenge is to create an easy-to-use, versatile and durable panel that provides thermal insulation of buildings and protection from adverse environmental influences.

The technical result is to increase the strength and service life of a facade building panel during operation by increasing the resistance of the panel to the adverse effects of the environment.

The task is achieved by the fact that the front facade insulating panel contains an outer layer of fiber cement and an inner layer of insulation. The layers are interconnected by the “dovetail” method. At one end, the outer layer is made in a stepped form, the upper step being made with a protrusion turned upwards, and at another opposite end, the outer layer is also made with a protrusion. The profile of the outer layer is made with the formation of a mechanical locking system with the possibility of engagement when mounting adjacent panels with each other.

The properties of fiber cement provide stable mechanical characteristics of the outer panel plate. Thereby providing shock strength, durability, appearance preservation under the influence of atmospheric moisture and ultraviolet.

The connection of the “dovetail” layers of insulation and fiber cement is carried out by mechanical closure and is not adhesive / adhesive, which ensures long-term operation of the panel.

A simple and reliable closure during installation of the panels is ensured by the presence of steps and protrusions on the outer layer of the panel.

Due to the presence of protrusions of the outer panel, the interface between the panels is protected from adverse environmental conditions (moisture access to the insulation and the facade of the building is excluded), therefore, the level of thermal protection of the enclosing structures increases and the life of the building as a whole increases.

The presence of locking elements significantly affects the technical result, since the connection of panels with locking elements is essentially hermetic and prevents moisture from entering the insulation without the use of additional sealing elements.

The essence of the proposed technical solution is illustrated with graphic material, where in FIG. 1 shows schematically a three-dimensional image of a cladding panel mounted on a facade; FIG. 2 is a diagram of the connection of the plates with each other during installation; FIG. 3 - view A is enlarged.

The combined cladding panel (Fig. 1 - Fig. 3) contains the outer layer 1 of fiber cement, for example, architectural fiber concrete of the M600 grade. The inner layer 2 of insulation is made of non-combustible material, for example, from extruded polystyrene foam or polyisocyanurate. The layers are interconnected through the dovetail connection 3.

As shown in the enlarged view A of FIG. 3 at one end, the outer layer 1 is made in a stepped form, the upper step 4 being made with a protrusion turned upwards; at the other opposite end, the outer layer is also made with a protrusion 6. The profile of the outer layer 1 is made to form a mechanical locking system with the possibility of engagement when mounting with other adjacent panels.

The front insulation panel is manufactured as follows. Pre-mechanically profiled insulation panel - technological and operational grooves are made on the surface. Further, on the panel installed on the conveyor, after several transitions, a molding solution of a given color is applied in layers and a fiber is introduced. The mold for casting is the insulation panel and part of the tooling. In the intervals between application, the profile of the fiber-cement layer is formed by using tools like broaching and forming rollers. After the molding is completed, the surface pattern is applied with profiling rollers. The molded panel is machined with a blade tool in order to manufacture mounting holes, imparting specified mechanical properties to the surface of the locking part of the panel. The ends of the panels can be made with the possibility of connecting horizontally by the “thorn-groove” method both for insulation and for fiber cement.

Installation of panels is carried out without limitation of weather conditions for temperature and humidity, i.e. year-round. The surface of the enclosing facade 7 is cleaned of dirt and flaking elements (Fig. 1). Geometric characteristics of the shape and flatness of the facade are controlled. Installation begins from the bottom of the facade by installing the panel on the starting plate (not shown in figure 1), which holds the lower edge of the panel. The panel is mounted at the top (hung) on the facade of the 7 threaded rod (with a screw or anchor) in a hole pre-marked and made in the facade. The next panel is mounted on the fastened panel on top (Fig. 2), and the process is repeated. It is allowed to install panels according to the scheme “one above the other” and according to the scheme “in a run-up. Horizontal joints are provided, for example, with a thorn-groove lock. The installation is completed by the “institution” of the upper fastening for the protection of the roof. Or steel finish plate.

An important result for architectural aesthetics and diversity of facades is the multivariance of possible panel profile drawings.

Thus, the proposed solution allows for simplicity, accuracy and versatility of all-weather installation, reducing cold bridges due to the original hooking of the panels among themselves, increasing the durability of cladding panels through the use of fiber cement boards with increased resistance to environmental influences.

Claims (1)

The front insulating panel containing the outer layer of fiber cement and the inner layer of insulation, characterized in that the layers are interconnected by means of a dovetail connection, the outer layer being stepped at one end, the upper step being made with a protrusion turned upwards, from the other opposite end, the outer layer is also made with a protrusion, while the profile of the outer layer is made with the formation of a mechanical locking system with the possibility of engagement when mounted with each other, see urchin panels.

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