RU216306U1 - Self-supporting double-glazed window - Google Patents

Abstract

The utility model relates to insulating glazing, in particular to a double-glazed window containing at least two panes arranged parallel to each other with a bearing profile. A double-glazed window is used in translucent structures containing solid glazing or glazing with an opening sash. The technical result of the claimed utility model is to increase the bending strength of the supporting double-glazed window. The self-supporting double-glazed window contains at least two glass plates located parallel to each other, interconnected by a distance frame placed along the contour, with the formation of a sealed space between the glass plates. Moreover, the outer surface of the distance frame and the space between the outer side surface of the distance frame and the glass plates are filled with sealant, and between the outer glass plates, at least on one side of the contour of the double-glazed window, a carrier profile with stiffeners and with additional fixation on the surfaces of the outer glass plates is integrated into the sealant layer. with a sealant. In this case, the supporting profile is made by pultrusion from a composite material containing at least one filler selected from the group: glass fiber, carbon fiber, basalt fiber, textile fibers, polymer fibers, and a matrix containing at least one component selected from the group: thermoset epoxy, polyurethane, phenolic, polyester resin.

Description

FIELD OF TECHNOLOGY

The utility model relates to insulating glazing, in particular to a double-glazed window containing at least two panes arranged parallel to each other with a bearing profile. The stekpopacket is used in translucent structures containing solid glazing or glazing with an opening sash.

BACKGROUND OF THE INVENTION

Known from the art is a method of installing double-glazed windows and other translucent structures in window frames. Frames serve as supports for translucent structures and are a load-bearing element. Window frames made of materials such as plastic, aluminum, wood, steel, etc., are designed to withstand functional and operational loads. Rigidity and profiling of the frame provide the load-bearing capacity of the frame and sufficient sealing of the sash along the contour. In particular, in the frames, the sealing and fixation of the double-glazed window is provided by clamping elements, which, in turn, narrow the light aperture and create an additional increase in the structure. There is moisture permeability at the joints of the seals in the gaps between the sash and the glass filling, which, in turn, reduces the service life of the structure and, due to the milling of drainage channels and insufficient sealing, increases the ventilation of the structure, and, as a result, leads to an increase in heat loss. In view of modern glazing standards, there is a technology for manufacturing double-glazed windows with a higher coefficient of heat transfer resistance than a window frame. Thus, in the classical version, in addition to reducing the light opening, the area of the cold part of the window also increases.

The disadvantage of traditional glazing is the complexity of manufacturing and the need for expensive equipment for the production and connection of the profile. In addition, for each thickness of the double-glazed window, its own set of clamping bars is required, the value of which depends on the selected profile. An important disadvantage of the classical profile system can also be noted the low bearing capacity and the tendency to sag of movable sashes and mullions, since the double-glazed window in the sashes and mullions is installed by expanding in the sash frame using installation cards and wedges, which can be identified as a separate negative factor. The glass in the glass filling is subject to diagonal point loads that adversely affect the resistance to glass breakage on large glazing formats, and as a result, the use of thicker glasses and / or the use of tempered glasses is required.

From the prior art patent RU 94040708 A1 "FRAMELESS INSULATED GLAZING AND METHOD FOR ITS MANUFACTURE" is known, the essence of which is the manufacture of double-glazed windows, which include glass and a gasket formed by a molded element containing several elastic, bending-hard and crossing filaments with each other passing perpendicular to the glass surfaces and forming a spacer with force closure between the glasses.

The disadvantage of this kind of design is the tendency to depressurization. Due to the pressure difference between the interior of at least two panes of the window system and the surroundings, the gas between the panes expands. By changing the pressure between the panes, large forces act on the adhesive layer between the window panes and the frame element of the window system. Thus, in prior art windows with bonded glass panes, these forces often cause the adhesive layer to separate, which leads to the separation of the window panes.

Thus, the tightness of the chamber formed by two glasses is violated, which leads to a decrease in the coefficient of resistance to heat transfer and a tendency to condensate on the glasses both from the outside and from the inside.

Another disadvantage is the perpendicular arrangement of the filaments relative to the glass, due to which the product is immune to bending loads both in the longitudinal and in the cross section, since the perpendicularly located filaments work well in compression and tension, which, as a result, affects the lower ability to perceive wind and snow loads if glass infill is used on the roof.

It is also known from the prior art that the vapor barrier of the connection of two elements is provided by a non-curing sealant (eg butyl or the like), the use of which is not mentioned in this patent. The use of such a sealant is mandatory in the manufacture of double-glazed windows.

Also, patent RU 76058 U1, publ. 09/10/2008, the essence of which is the manufacture of window structures, namely the manufacture of a special form of metal profiles with the possibility of integrating insulating glass units of various configurations, including large sizes.

The disadvantage of this design is the material from which the profile system is made. The profile is made of metal, which is why thermal breaks are required to ensure thermal parameters, which complicates the design and imposes a number of restrictions that make it impossible or greatly complicate the manufacture of a profile of small width. Also, the metal profile can corrode in the atmospheric environment.

Another disadvantage is the impossibility of reliable integration of the double-glazed window into the profile by gluing. Since the coefficient of linear expansion of glass differs from the coefficient of linear expansion of metal, which is why during operation the glass and the profile make cyclic movements relative to each other, which, in turn, creates shearing and tearing forces, which over time affects the bearing properties of the substance connecting profile and glass construction.

Also known from the prior art patent RU 2708215 C1, publ. 12/04/2019, which describes an adaptive insulating glass unit, with the possibility of integrating it into various profile systems. The peculiarity of the execution of this double-glazed window is that it consists of at least two extreme panes and at least one central one, and two extreme panes are always larger than the central ones. Glasses are interconnected by spacers and form sealed chambers. A profile made of wood or a polymeric material, consisting of two parts, is glued to the inner surface of each of the side windows, and an expanding profile is inserted between the two profiles to ensure pressure.

The disadvantages of this design are the following:

- a profile made of wood does not have a uniform arrangement of fibers, and, accordingly, does not have constant strength characteristics along the length of the profile.

- a profile made of wood has the properties of being saturated with moisture, condensation may occur in its volume, which over time contributes to a change in the strength properties of wood, which, in turn, affects the durability of the structure;

- a profile made of a polymeric material does not have the disadvantages described in the case of a profile made of wood, but also does not have high strength characteristics in relation to, for example, pultrusion composite materials in which pretensioned threads and / or fibers of various kinds act as a reinforcing element and multiply increase the bearing capacity and strength characteristics of the material;

- a profile consisting of two parts with equal overall dimensions is inferior to a single-component profile in terms of strength characteristics, which is why an increase in the size and weight of the glazing entails a significant change in the profiles glued to the inner surfaces of the outer panes. In addition, the assembly process becomes more complicated, since it is necessary to position two profiles in order to comply with the geometric parameters of the product;

- due to the fact that the outer panes in these double-glazed windows are always larger than the inner ones, there is a problem of assembling such double-glazed windows on existing double-glazed assembly lines. The problems are related to the automatic positioning of the glasses relative to each other and automatic secondary sealing. Such problems determine either the manual assembly of double-glazed windows, which slows down the production process, or the manufacture of expensive additional special equipment;

- due to the fact that the outer panes in these double-glazed windows are always larger than the inner ones, there is a problem of reducing the light opening due to the fact that an increase in the outer glass (facing the street) entails an increase in the external profile of the system, or the impossibility of using another lower profile.

DISCLOSURE OF UTILITY MODEL

The objective of the claimed utility model is to manufacture a system of profiles from a composite material based on glass fiber and / or carbon fiber and / or basalt fiber and / or other fibers, interconnected by a binder based on epoxy, polyurethane, phenolic, polyester or other resins and / or their mixtures, the integration of glass filling in them, the development of technical solutions for the manufacture of window systems of increased rigidity and load-bearing capacity. It is possible to add various kinds of components to the composition of the binder that change the color and/or physical and mechanical characteristics of the product.

The technical result of the claimed utility model is to increase the bending strength of the supporting double-glazed window.

The specified technical result is achieved due to the fact that the self-supporting double-glazed window contains at least two glass plates located parallel to each other, interconnected by a distance frame placed along the contour, with the formation of a sealed space between the glass plates. Moreover, the outer surface of the distance frame and the space between the outer side surface of the distance frame and the glass plates are filled with a layer of primary sealant, and between the outer glass plates, at least on one side of the double-glazed window contour, a carrier profile with stiffeners and with additional fixation is integrated into the primary sealant layer. on the surfaces of the outer glass plates with a layer of secondary sealant. In this case, the carrier profile is made by pultrusion from a composite material containing at least one filler selected from the group: glass fiber, carbon fiber, basalt fiber, textile fibers, polymer fibers, and a matrix containing at least one component selected from the group: thermoset epoxy, polyurethane, phenolic, polyester resin.

A low-emissivity conductive layer is deposited on the outer or inner surface of at least one glass plate.

A film with variable transparency is deposited on the outer or inner surface of at least the glass plate.

At least one glass plate is a two-layer glass consisting of two glasses interconnected by a layer of an electrochromic ultraviolet (UV) curing substance, while each surface of these glass plates interacting with a layer of electrochromic UV curing substance is coated with a conductive low emission layer.

A multifunctional coating is applied to the outer or inner surface of at least one glass plate.

An energy-saving coating is applied to the outer or inner surface of at least one glass plate.

At least one glass plate is a triplex consisting of at least two glasses interconnected by a UV-curable adhesive layer or a layer of thermoplastic material.

An armored film is applied to the outer or inner surface of at least one glass plate.

Blinds are installed in the hermetic space formed by two parallel glass plates, one of which is turned inside the room.

The sealed space is filled with an inert gas.

BRIEF DESCRIPTION OF THE DRAWINGS

Fig. 1 - Self-supporting double-glazed window.

1 - glass plate of a self-supporting double-glazed window; 2 - remote frame; 3 - space filled with secondary sealant; 4 - air chamber; 5 - carrier profile; 6 - frame profile; 7 - air chamber; 8 - external elastic sealing element; 9 - internal sealing element; 10 - middle elastic sealing element.

IMPLEMENTATION OF UTILITY MODEL

The self-supporting double-glazed window contains at least two glass plates (1) located parallel to each other, interconnected by a spacer frame (2) placed along the contour between the glass plates (1), with the formation of a sealed space between the glass plates (1).

Moreover, the outer surface of the distance frame (2) and the space between the outer side surface of the distance frame (2) and the glass plates are filled with a layer of primary sealant, and between the outer glass plates (1) at least on one side of the contour of the double-glazed window, the layer of primary sealant is integrated load-bearing profile (5) with stiffeners and with additional fixation on the surfaces of the outer glass plates (1) using a layer of secondary sealant. In this case, the carrier profile (5) is made by pultrusion from a composite material containing at least one filler selected from the group: glass fiber, carbon fiber, basalt fiber, textile fibers, polymer fibers, and a matrix containing at least one component selected from groups: thermoset epoxy, polyurethane, phenolic, polyester resin.

The load-bearing double-glazed window may contain one hermetic chamber located between two outer glass plates (1), one of which is facing the inside of the room, and the other - the outside. Also, the supporting double-glazed window may contain more than one sealed chamber, while at least one inner glass plate (1) is located between the two outer glass plates (1).

In the carrier profile (5), the following can be made: grooves for installing window fittings, grooves for elastic sealing elements, grooves for laying wires, and / or cavities and / or grooves for other purposes, for example, an air chamber (4), which performs the function of a thermal break, therefore, the carrier profile (5) is not prone to freezing and corrosion. Also, the air chamber (7) located in the frame profile (6) performs the same function as the air chamber (4).

As a sealant, silicone, thiokol, polyurethane sealants of secondary sealing are used.

A low-emissivity conductive layer is applied to the outer or inner surface of at least one glass plate (1) (one of the outer or one of the middle ones). The surface of said layer can be laser-etched with a pattern in the form of geometric shapes and/or lines, these geometric shapes and/or lines being made to change the electrical resistance of the product, which in turn affects the electrical power of the product. To ensure current supply to the low-emissivity current-conducting layer, current-carrying busbars are deposited on the surface of the low-emission current-conducting layer by gas-dynamic spraying of powder metals or by another method, to which contact wires are connected by soldering or by another method. When an electric current is passed through a low-emissivity conductive layer, its surface heats up and thermal energy is transferred via infrared radiation.

On the outer or inner surface of at least the glass plate (1) (one of the outer or one of the middle) is applied a film with variable transparency (PDLC film). The PDLC film contains contact pads made of metallic copper foil with contact wires attached by soldering or otherwise. When an electric current is passed through such a film, the transparency of the translucent structure changes.

At least one glass plate (1) (one of the outer or one of the middle) is a two-layer glass, consisting of two glasses interconnected by a layer of an electrochromic UV curing substance, while on each surface of these glass plates, interacting with A conductive low-emissivity layer is applied with an electrochromic UV curing agent. Along the perimeter of each of the two glass plates (1), on the surface with a low-emission coating applied, current-carrying busbars are applied by gas-dynamic spraying of powder metals or by another method, to which contact wires are connected by soldering or by another method. The glass plates (1) arranged in this way are connected to each other by means of an electrochromic UV curing agent, which, when an electric current flows through it, changes the light transmission capacity.

A multifunctional coating is applied to the outer or inner surface of at least one glass plate (1) (one of the outer or one of the middle ones), which allows reflecting infrared radiation (sun rays) penetrating from the street, and reflecting infrared radiation from the accumulated heat in the room , which allows you to more clearly separate the microclimate in the room from the conditions of the street.

An energy-saving coating is applied to the outer or inner surface of at least one glass plate.

At least one glass plate is a triplex consisting of at least two glasses interconnected by a UV-curable adhesive layer or a layer of thermoplastic material, such as EVA (Ethylene Vinyl Acetate) or PVB (Polyvinyl Butyral). Due to the presence of such a triplex in the composition of the double-glazed window, the double-glazed window may have the properties of noise insulation and / or burglary resistance.

An armored film is applied to the outer or inner surface of at least one glass plate, due to the presence of which the double-glazed window has burglary resistance and/or armor protection.

In the hermetic space formed by two parallel glass plates, one of which is facing the inside of the room, blinds are installed containing lamellas located inside the hermetic space and a blinds control mechanism controlled by a magnetic, electrical, mechanical or other way outside the hermetic chamber of the double-glazed window.

The sealed space is filled with an inert gas: helium, argon, etc.

Next, we give a description of the assembly of a translucent structure in the form of a single-chamber double-glazed window for an opening sash.

The carrier profile (5) and the frame profile (6) produced by pultrusion are cut with a diamond blade end saw at the required angle and a certain size, in accordance with the required size of the window (translucent structure). The frame profile (6) and the supporting profile are connected at the cut points with corner connectors. The profile joint (5, 6) can be sealed with silicone or other suitable UV resistant sealant.

Further (for a single-chamber double-glazed window), two glass plates (1) are cut out for the opening sash, based on the dimensions of the structure and the formula of the double-glazed window, and the outer glass plates (1), one of which faces the inside of the room, and the other - the outside, can be painted (and / or otherwise processed) protrusions around the perimeter. Glass protrusions can be made both to ensure that the sash adjoins the fixed frame, since, for example, a sealing elastic element can be installed on them, and to hide sealing layers and / or spacers and / or mullions, which gives the final product an aesthetic appearance .

The two outer glass plates (1) are connected by means of a spacer (2), on which a sealant is applied, forming a primary sealing layer. Then, a sealant is applied to the outer surface of the spacer frame to form a secondary sealing layer between the glass plates (1), into which the supporting profile (5) is glued and additionally fixed on the surfaces of the outer glass plates with a sealant, with each glass plate (1) in the composition double-glazed window, each spacer and carrier profile are interconnected by one layer of secondary sealing and form a connected system of increased rigidity, in which each element takes part of the total operational loads. The assembled double-glazed window is inserted into the assembled frame of profiles (6) and fixed in it with the help of hinges and a sash opening/closing mechanism. The carrier profile (1) contains an external elastic sealing element (8), and the frame profile (6) contains a middle elastic sealing element (10), designed to seal the opening sash from the outside (for example, from the street side). On the inner surface of the glass plate (1), facing the inside of the room, an internal elastic sealing element (9) is fixed, designed to seal the opening sash from the inside (for example, from the side of the room). External (8) and internal (9) elastic sealing elements are located on the movable part of the structure. This arrangement makes it possible to manufacture an external elastic sealing element of a special configuration, namely a combined sealing profile of an enveloping type with a drip tint, in which the likelihood of drops, for example, rain falling into the space between the frame and the double-glazed window, is minimized, this effect cannot be achieved when installing the seal on the fixed part of the frame.

The profile made by pultrusion, in turn, entails an increase in the rigidity of the profile, while unlike PVC profiles and comparable to aluminum systems in strength, it has better thermal characteristics. Unlike aluminum profile systems, a pultrusion profile may include air chambers that perform the functions of a thermal break, and the profile material itself is not prone to freezing and corrosion. Thus, it is possible to manufacture less massive profile systems, comparable in strength to classical profile systems of similar dimensions, or superior to them.

The die for extrusion of the profile by pultrusion is designed in such a way that it can take into account fitting grooves, grooves for seals, air chambers acting as a thermal break, stiffening ribs working on twisting and / or bending, thereby giving the product resistance to various loads. .

It is possible to manufacture a single-chamber, two-chamber or three-chamber double-glazed window with a carrier profile integrated in the secondary sealing layer. This solution makes it possible to install a double-glazed window with an integrated load-bearing profile in a fixed frame. The supporting profile may have special grooves for installing fittings and / or rubber seals to ensure the mobility of the sash and the tightness of its adjoining when closing. The supporting profile is highly rigid and can be used instead of the classic PVC and aluminum frame used for moving and fixed window sashes.

In the field of construction, there is a problem in the glazing of facades and roofs with sheets of glass filling of large sizes. These problems are due to the fact that wind and snow loads acting on the glass filling entail the construction of complex, heavy and expensive structural solutions.

The use of the technology makes it possible to manufacture facade and roof translucent structures of increased bending rigidity, respectively, capable of absorbing large wind and snow loads, compared to the classic glass filling of structures, without a significant increase in the weight of the glass filling. The assembly of double-glazed windows using this technology makes it possible to assemble such double-glazed windows on classic glass-packet assembly lines, including those with automatic secondary sealing. Thus, the rigidity of the elements of such glass filling allows the use of lighter constructions for the construction of facade and roof glazing, with such functions as electric space heating, snow melting, variable transparency, changes in light transmission, including large sizes.

The integration of the carrier profile with stiffeners and with additional fixation on the surfaces of the outer glass plates using a layer of secondary sealant allows the profile to experience shock, bending, twisting loads, while not transferring them directly to any of the panes of the double-glazed window. All loads experienced by the load-bearing profile are transferred to the panes through the secondary sealant, which has well-defined elastic properties. Thus, the sealant of the secondary sealing is a damping element, which allows the double-glazed window with a bearing profile to experience shock, bending, twisting loads without destroying the integrity of the glasses of the double-glazed window, which, in turn, increases the strength of the translucent structure, compared to the profile into which at least at least one pane of an insulating glass unit that bears the loads on the edge of the glass, which in turn is the most breakable part of the glass plate.

The utility model has been disclosed above with reference to a specific embodiment. For specialists, other embodiments of the utility model may be obvious, without changing its essence, as it is disclosed in the present description. Accordingly, the utility model should be considered limited in scope only by the following claims of the utility model.

Claims (10)

1. Self-supporting double-glazed window containing at least two glass plates located parallel to each other, interconnected by a spacer placed along the contour, with the formation of a sealed space between the glass plates, and the outer surface of the spacer and the space between the outer side surface of the spacer and filled with glass plates with a layer of primary sealant sealant, while between the outer glass plates on at least one side of the double-glazed window contour, a carrier profile with stiffeners is integrated into the primary sealant layer with additional fixation on the surfaces of the outer glass plates using a layer of secondary sealant sealant, moreover The supporting profile is made by pultrusion of a composite material containing a fiber filler and a thermosetting resin matrix. 2. Self-supporting double-glazed window according to claim 1, characterized in that the filler is selected from the group: glass fiber, carbon fiber, basalt fiber, textile fibers, polymer fibers, and the matrix is selected from the group: thermoset epoxy, polyurethane, phenolic, polyester resin. 3. Self-supporting double-glazed window according to claim 1, characterized in that a low-emissivity conductive layer is applied to the outer or inner surface of at least one glass plate. 4. Self-supporting double-glazed window according to claim 1, characterized in that a film with variable transparency is applied to the outer or inner surface of at least one glass plate. 5. Self-supporting double-glazed window according to claim 1, characterized in that at least one glass plate is a two-layer glass consisting of two glasses interconnected by a layer of an electrochromic UV curing substance, while on each surface of these glass plates, interacting with a layer of electrochromic UV curing agent, a conductive low-emissivity layer is applied. 6. Self-supporting double-glazed window according to claim 1, characterized in that a multifunctional coating is applied to the outer or inner surface of at least one glass plate. 7. Self-supporting double-glazed window according to claim 1, characterized in that an energy-saving coating is applied to the outer or inner surface of at least one glass plate. 8. Self-supporting double-glazed window according to claim 1, characterized in that at least one glass plate is a triplex consisting of at least two glasses interconnected by a UV-curable adhesive layer or a layer of thermoplastic material. 9. Self-supporting double-glazed window according to claim 1, characterized in that an armored film is applied to the outer or inner surface of at least one glass plate. 10. A self-supporting double-glazed window according to claim 1, characterized in that blinds are installed in the sealed space formed by two parallel glass plates, one of which faces the inside of the room.

Images