IT202100026258A1 - Window frame profile - Google Patents

Description

Window frame profile

Technical field

The invention generally concerns the construction field. More? in particular, the invention refers to window frame profiles characterized by a low heat exchange coefficient and high rigidity? torsional, that is? non-deformable during operation and during installation, which avoids loss of seal due to air infiltration.

State of art

Design solutions for windows are known, in which the wooden parts are reinforced with molded plastic spacers. This structure? characterized by reduced conductivity? thermal, while the rigidity? does not change due to the fact that the transverse dimensions do not change, and the cutting modules of wood and plastic are similar.

Window profiles made of plastic material are also known, having two main support chambers and some auxiliary chambers filled with air. These chambers reduce the heat transfer coefficient. The rigidity? torsional strength of the frames made with these profiles? relatively low due to high flexibility? of plastic. To increase rigidity? of large frames, for example open steel profiles with a rectangular section or plate-shaped section are inserted into the frames. From the theory of torsion bars it follows that open section bars have torsional stiffness several tens of times lower than similar closed profiles. Consequently, the rigidity? of the window frame and the sash frame would change slightly. The introduction of steel reinforcements virtually does not reduce (and can even increase) the heat transfer coefficient of a window frame due to high conductivity. temperature of the steel, and therefore the thermal performance of the window would deteriorate.

To reduce heat losses, frames with multi-chamber sections have been introduced, in which plastic spacers with a high conductivity coefficient are used in the two main (larger) chambers. lower than that of steel, which reduces the heat transfer coefficient of the frame, while influencing the rigidity? of the structure.

Polish patent PL225174B1 describes a method of manufacturing windows consisting of frame profiles and frame profiles of a multiple window. rooms. Openings are made in these profiles to suck air from the chambers. Is the void like this? produced in the rooms guarantees better parameters of the thermal and acoustic insulation coefficient.

Another Polish patent PL184029B1 describes a window design consisting of multi-profiles. chambers of a window frame and a casement. Inside the chambers are embedded metal reinforcement strips coated with a heat-reflecting layer, which translates into a higher conductivity coefficient. lower temperature. Yet another Polish patent PL219804B1 describes a window frame having window frame elements in the form of multi-chamber plastic profiles, reinforced with metal profiles placed inside the multi-chamber profile. Reinforcement and stiffening inserts made of low conductivity material are inserted into the chambers of the plastic profile. thermal, preferably wood.

Polish patent application P.383438 describes a PVC window or door profile, consisting of walls forming in section a box-like structure with internal chambers in which? inserted a longitudinal reinforcement reinforcement that extends along the profile. The guardian? consisting of a PVC-based composite material and a shredded lignocellulosic material, preferably a wood powder.

Yet another Polish patent PL232782B1 describes a window having a frame and a sash made of multi-layer PVC profiles. chambers, with reinforcing metal inserts placed in the space of some profiles.

Polish patent application P.404064, in turn, describes a set of profiles with thermal reinforcement, comprising a frame profile and a sash frame profile. Do these profiles have a plurality? of walls that divide the inside of the profile into chambers that extend along the longitudinal axis of the frame profile and the frame profile. One of the chambers houses a stiffening element with at least one reinforced wall and an insulating material that remains in contact with the stiffening element. The insulating material? a plastic insert, e.g. in expanded polyurethane, airgel or polystyrene. The stiffening element? a metal profile. This solution provides better resistance to bending in the plane parallel to the glass surface.

Summary of the invention

Purpose of the invention? provide a window design with a low heat exchange coefficient, but at the same time characterized by high rigidity? torsional.

According to the present invention, a window frame profile having a plurality of of chambers formed by a system of longitudinally developing walls, in which in at least one of these chambers, at least for part of its length, a stiffening element and an insulating material are inserted. The stiffening element? a closed profile made of a composite reinforced with textile material and filled with an insulating material.

Preferably, the textile material? made of natural or artificial fibers or a combination thereof.

The textile material? a fabric, and more? preferably a glass fabric.

Preferably, the section ? made of a composite that is a glass fiber laminate.

Preferably, the closed-section stiffening element is located in the main bedroom large or in at least one additional room larger? small.

Preferably, the stiffening element in the form of a closed profile adheres tightly to the internal surface of the chamber along its entire length, and the insulating material with a low heat exchange coefficient sealingly fills the inside of the profile.

Advantageous effects of the invention

The solution according to the invention allows to increase the rigidity? torsional strength of window or door frames, which prevents them from deforming and losing their seal against air infiltration, as well as? to reduce the heat transfer coefficient, which in turn reduces heat losses.

Brief description of the figures

The invention? presented in one embodiment in the attached drawings, in which:

Fig.1 ? shows a window frame profile in cross section.

Fig.2 ? shows a profile of the frame in a cross section.

Fig. 3 ? shows an assembly of components from Fig. 1 and Fig. 2 in a window.

Detailed description of a preferred embodiment of the invention Fig. 1 and Fig. 2 show two embodiments of a frame profile according to the invention, in which the frame profile shown in Fig. 1 is a profile of a window frame and the frame profile shown in Fig. 2 ? a frame profile of a door leaf.

The window frame profile 1 shown in cross section in Fig. 1 ? made as a multi-structure rooms uniting a plurality? of walls 5 extending longitudinally which divide the frame profile 1 into a plurality? of chambers 3 filled with air, 4. In this example, the profile of the frame 1 has a plurality? of additional rooms more? small 4 and a main bedroom plus? large 3. The frame profile 1 ? mostly made as a single piece of plastic, usually PVC, by extrusion. In the main room 3? inserted a stiffening element closely adhering to its walls, in the shape of a closed section 6 with a cross section corresponding to the shape of the main chamber 3, in this case with a rectangular section. Section 6? made of a composite reinforced with textile material and filled with an insulating material 7 with a low heat exchange coefficient, that is? much inferior to steel. In a preferred embodiment, the composite used to make section 6? a laminate reinforced with fabric or generally textile material. Can the fabric be made of artificial or natural fibers or a combination thereof. Preferably, laminate? formed by impregnating a glass fiber fabric with a resin, resulting in a stiffening element with a very low heat exchange coefficient and high rigidity. torsional. The insulating material 7 which sealingly fills the profile 6 is, for example, polyurethane foam.

The stiffening element in the form of a closed profile 6 can? also be inserted in one or more? additional rooms 4.

The structure of the frame profile 2 of a window, as shown in Fig. 2, is? substantially the same as that of the frame profile 1 of a window frame of Fig.1 and therefore it will not be further described in detail.

Fig.3 shows, in turn, a section of a window which includes a frame profile 1 of the window frame of Fig.1 and a frame profile 2 of a sash which is hinged to the window frame. The frame profiles are connected to each other with gaskets 10. In the presented embodiment, both the frame profile 1 of the window frame and the frame profile 2 of the sash have a stiffening element, placed in the main chamber 3, below shape of a section 6 well adherent to the main chamber 6, made of a composite reinforced with textile material and filled with an insulating material 7. In this embodiment, the door also has a filling in the form of a window 8 which is in the form of a unit window? composed of three glass panels. The glazing? installed in the frame profile 2 with a longitudinal strip 9 and gaskets 10. The introduction of closed sections made of glass fabric-based laminates significantly increases the rigidity? torsional strength of a window element, which reduces the deformation of windows, especially large ones.

The use of laminate sections filled with thermal insulation, where both the laminate and the thermal insulation have much lower heat conduction coefficients? lower than steel, contributes to the reduction of the heat exchange coefficient, and therefore to the reduction of heat losses in the environments.

Claims (8)

Claims 1. Window frame profile (1, 2) having a plurality? of chambers (3, 4) formed by a system of longitudinal walls (5), in which in at least one of these chambers, at least along a part of its length, a stiffening element and an insulating material are inserted, characterized in that the stiffening element? a closed profile (6) made of reinforced composite textile material and filled with an insulating material (7). 2. Window frame profile according to claim 1, characterized in that the textile material is made of natural or artificial fibers or a combination thereof. 3. Window frame profile according to claim 1 or 2, characterized in that the textile material is a fabric, preferably a glass fabric. 4. Window frame profile according to claim 1 or 2 or 3 characterized by the fact that the composite is a laminate. 5. Window frame profile according to claim 4 characterized in that the laminate is made of fiberglass. 6. Window frame profile according to claim 1 characterized in that the closed section stiffening element (6) is located in the main bedroom large (3) or in at least one additional room larger? small. 7. Window frame profile according to claim 1 or 6 characterized in that the closed-section stiffening element (6) is arranged in at least one further room (4) more? small. 8. Window frame profile according to claim 1 or 6 or 7 characterized in that the closed-section stiffening element (6) adheres tightly to the internal surface of the chamber (3, 4) along its entire length, and the insulating material (7) with a low heat exchange coefficient seals the inside of the section.