DE202020105075U1 - Frame construction for a window, a door or a fixed glazing - Google Patents

Abstract

Frame construction for a window, door or fixed glazing, comprising: - a frame profile (2, 3), the material of which has a thermal conductivity of less than 1.0 W / mK and - comprises a sash frame (2) and - a window frame (3); - A vacuum insulating glass unit (1) held in a glass inset (S3) of the frame construction; wherein the vacuum insulating glass unit (1) has a heat transfer coefficient Ug of at most 1.0 W / (m2K); characterized in that- the frame structure has on the outside a metal cover (30) of an outer insulating area, the wall thickness of which is in the range between 0.5mm and 3mm and the distance to the vacuum insulating glass unit (1) is at least 2mm and preferably at least 3mm The area of the glass insert comprises a thermal coupling element (5; 15) with a thermal conductivity which is increased by a factor of at least 10 and preferably by a factor of 20 and particularly preferably by a factor of 300 compared to the material of the frame profile of the sash frame (2); and an outer insulation thickness (S1) of the outer insulation area in the direction of heat flow is at least a factor of 3, preferably at least a factor of 4, greater than the thickness (S2) of an inner seal (6).

Description

Field of invention

The invention relates to a frame construction for a window, a door or a fixed glazing comprising a frame profile and a vacuum insulating glass unit.

State of the art

Vacuum insulating glasses are increasingly being used in frame constructions because they have very good thermal insulation. Vacuum insulating glass units have Ug values that are below 1.0 W / (m ² K) and often even between 0.4 W / (m ² K) and 0.5 W / (m ² K).

Due to the fact that the overall thickness of vacuum insulating glass is considerably smaller than that of standard insulating glass, frame constructions for vacuum insulating glass have a different structural design compared to frame constructions for standard insulating glass.

Vacuum insulating glass units, however, have two problems, both of which are caused by the formation of the edge bond of conventional vacuum insulating glass units. Conventional vacuum insulating glass units namely have two glass elements arranged at a relatively small distance from one another, between which there is a space between the panes which is evacuated. The two panes of glass are held at the desired distance by several supports, which is approx. 0.15 mm to 0.7 mm. In order to be able to maintain the negative pressure in the space between the panes, a vacuum-tight edge seal must be provided between the panes of glass. The edge seal usually consists of metal (brass or stainless steel) or ceramic. Due to the edge bond of vacuum insulating glass elements with its small thickness, there are high linear heat transfer coefficients of the frame profile and built-in glass unit. High linear heat transfer coefficients in the edge area mean a deterioration in the overall thermal insulation of the vacuum insulating glass unit.

In the state of the art, this problem is taken into account in that good thermal insulation is ensured on both sides of the vacuum insulating glass unit. At the same time, however, care must be taken to ensure that the weather-side frame profile is sufficiently durable.

The second difficulty is that due to the high linear heat transfer coefficient, the surface temperature in the transition between the frame profile and the vacuum insulating glass unit on the room side drops. This effect occurs with every frame material, but is particularly pronounced for frame profiles that have poor heat conduction compared to metal.

To assess a possible risk of condensation, the surface temperature in the transition between the frame profile and the vacuum insulating glass unit is determined on the basis of selected standardized boundary conditions. The standard boundary conditions are an outside air temperature of -10 ° C and an interior temperature of + 20 ° C. The standardized contact resistances are also included in the calculation of the surface temperature in the transition between the frame unit and the vacuum insulating glass unit. It must be determined whether under standard interior conditions at + 20 ° C and a relative humidity of 50% condensation water is to be expected. The dew point is not reached when the surface temperature in the transition between the frame profile and the vacuum insulating glass unit falls below 9.3 ° C.

From a relative humidity of 80%, mold can also form at a temperature below 12.6 ° C.

Presentation of the invention

On the basis of the problems outlined above of a possible below the dew point of the surface temperature in the transition between the frame profile and a vacuum insulating glass unit, the object of the invention is to propose a frame construction with a vacuum insulating glass unit in which there is a risk of condensation forming even with a frame profile made of a material with low thermal conductivity can decrease.

This object is achieved by a frame construction for a window, a door or fixed glazing with the features of claim 1 and a building envelope with the features of claim 10. Preferred embodiments follow from the remaining claims.

The frame construction according to the invention for a window, a door or a fixed glazing comprises a frame profile, the material of which has a thermal conductivity of less than 1.0 W / mK and comprises a casement and a frame. Furthermore, the frame construction comprises a vacuum insulating glass unit held in the frame construction with a glass inset, the vacuum insulating glass unit having a heat transfer coefficient of at most 1.0 W / (m ² K). The frame construction is characterized in that the frame construction is on the outside has a metal cover of an outer insulating area whose wall thickness is in the range between 0.5 mm and 3 mm and whose distance from the vacuum insulating glass unit is at least 2 mm and preferably at least 3 mm. Furthermore, the frame construction is characterized in that it comprises a thermal coupling element on the room side in the area of the glass inset with a thermal conductivity that is increased by at least a factor of 10 and preferably by a factor of 20, and particularly preferably by a factor of 300, compared to the material of the frame profile of the casement . Furthermore, according to the invention, an outer insulation material thickness of the outer insulation area in the heat flow direction is at least a factor of 3, preferably a factor of at least 4, greater than the thickness of an inner seal.

Even when using aluminum, the thermal coupling element can have a thermal conductivity that is 1000 times higher than that of a frame profile.

The basic idea of the invention consists in transporting heat from the inside of the room to the area in the transition between the frame profile and the vacuum insulating glass unit, which is critical in terms of falling below the dew point. By providing a thermal coupling element according to the invention in the area of the glass inset, the room-side surface temperature in the transition between the frame profile and the vacuum insulating glass unit, which when an inner seal is used, corresponds to the transition area between the inner seal and the inner glass surface, can be significantly increased. Since the heat transport through the thermal coupling element is only a very local measure, the other thermal parameters, in particular the overall thermal insulation of the glass frame element and the linear heat transfer coefficient of the frame profile and built-in glass element, are hardly changed. The metal cover of the outer insulation area improves the visual appearance of the frame profile in the outer insulation area and increases the durability of the frame construction, especially when using PVC or wood. It has surprisingly been shown and could also be verified within the scope of simulation calculations that such a metal cover does not noticeably worsen the condensation situation on the room side, provided the material thickness of the metal cover does not exceed 3 mm and preferably 2 mm and the metal cover at least 2 mm and preferably at least 3 mm is spaced from the vacuum insulating glass unit. The distance is particularly preferably 5 mm, which corresponds to the thickness of the outer seal that is usually used. This minimum distance between the metal cover and the vacuum insulating glass unit also prevents contact between the metal cover and the glass surface of the vacuum insulating glass unit in the event of wind suction. The maximum material thickness limits the heat flow through the metal cover and the distance to the vacuum insulating glass unit ensures that a heat insulating element is interposed between the metal cover and the vacuum insulating glass unit, whereby the heat transport from the outer frame to the vacuum insulating glass unit is reduced and this area still functions despite the metal cover fulfilled as the outer insulation area.

The solution according to the invention enables the absence of condensation water at an outside air temperature of up to -20 ° C.

The linear heat transfer coefficient of the edge area of vacuum insulating glass is higher than that of standard insulating glass. Therefore, in contrast to standard insulating glass, vacuum insulating glass often cannot be installed free of condensation water despite a thermal coupling. By providing a correspondingly increased outer insulation thickness in the heat flow direction in cooperation with a glass insert of not less than 15 mm, the frame construction according to the invention can also be used with a vacuum insulating glass unit.

The outer insulation thickness is usually made up of the total thickness in the heat flow direction of the frame profile and the outer seal.

The frame construction according to the invention is of particular interest when the material of the frame profile has a thermal conductivity of less than 1.0 W / mK, since the risk of a local dew point dropping below the dew point is particularly high with frame profiles with low heat conduction.

According to a preferred embodiment of the invention, the frame construction has a stop on the room side, which is provided in the form of a glazing bead or a fixed stop, the stop on the room side comprising the thermal coupling element. Calculations have shown that the integration of the thermal coupling element in a stop on the room side is particularly effective. Of course, other factors also play a role, such as the design of an inner sealing strip, which represents an additional thermal resistance and consequently reduces the effect of the thermal coupling.

According to a preferred embodiment of the invention, the frame profile of the sash is next to that provided Metal cover made of wood, integral foam, GRP, CK or thermoplastics, especially PVC, PP or PA. These materials have a thermal conductivity of sometimes well below 1.0 W / mK and can be used in the frame construction according to the invention, since the coupling element can solve the problems associated with frame profiles made of very good heat-insulating material of a local dew point falling below. The frame profile of the casement can also be a composite profile made of wood or rigid foam or a thermoplastic and rigid foam, the inner part of the composite profile being made of rigid foam and the inside and outside consisting of wood or thermoplastic.

The glass inset of the vacuum insulating glass unit is preferably between 15 mm and 25 mm. A glass inset of less than 15mm increases the risk of condensation despite thermal coupling. A glass inset between 15mm and 25mm has proven to be particularly suitable, on the one hand, to be able to fix the vacuum insulating glass unit without, however, providing too large a glass inset. Too high a glass inset is negative in terms of the required frame width, which should not be too large for reasons of design and incidence of light. In addition, if the glass inset is too high, it also has a negative effect on the overall thermal insulation of the window, as the frame is always less thermally insulating than the undisturbed vacuum insulating glass surface.

In the context of the overall thermal optimization of the frame construction according to the invention, it has proven to be advantageous if the frame construction further comprises an insulating element which is located on the outside in the area of the glass insert of the vacuum insulating glass unit. Such an insulating element represents a measure to reduce the linear heat transfer coefficient of the frame profile and the built-in vacuum insulating glass element. The provision of the insulating element arranged on the outside in the area of the glass insert thus represents a flanking measure in order to reduce the risk of the inner glass surface falling below the dew point in the transition area to the inner seal.

The thermal coupling element preferably comprises metal at least in some areas and is preferably a glass strip made of aluminum. Metallic materials have a high thermal conductivity, which, however, is within a relatively large range. Stainless steel has a thermal conductivity of approx. 15 W / mK, while aluminum has a thermal conductivity of approx. 160 W / mK. In general, however, metal is particularly suitable for producing the thermal coupling. A particularly effective measure is the provision of a glass strip made of aluminum with the aid of which the area at risk of falling below the dew point can be effectively coupled to the indoor climate.

According to an alternative preferred embodiment, the thermal coupling element can be aluminum foil with which the glass strip or the stop are covered. These solutions make it possible to produce a visually appealing solution, especially if an optically visible aluminum strip on the inside of the room is not desired.

Alternatively, the glazing bead can be coated with metal in certain areas or completely.

According to a preferred embodiment of the invention, the thickness of an outer seal in the heat flow direction is at least 50% greater than the thickness of an inner seal. In this way, on the one hand, the linear heat transfer coefficient of the frame profile and the vacuum insulating glass unit can be reduced by providing a well-insulating outer seal. On the other hand, an inner seal with a small thickness has a lower heat transfer resistance, which enables the most effective possible thermal coupling between the critical area in terms of falling below the dew point and the indoor climate.

Preferably the metal cover ( 30th ) made of aluminum When using PVC as the material for the frame structure, the metal cover is often coated in dark gray tones, mainly for visual reasons, while when using a frame structure made of wood, the metal cover is often coated in the color of the frame structure.

Finally, the invention also relates to a building envelope comprising a frame construction according to the invention.

Figure list

• 1 einen Schnitt durch ein Fensterprofil nach einer ersten Ausführungsform der Erfindung;
• 2 einen Schnitt durch ein Fensterprofil nach einer zweiten Ausführungsform der Erfindung;
• 2a eine abgewandelte Variante der Ausführungsform nach 2;
• 3 einen Schnitt durch ein Fensterprofil nach einer dritten Ausführungsform der Erfindung;
• 4 einen Schnitt durch ein Fensterprofil nach einer vierten Ausführungsform der Erfindung;
• 4a eine abgewandelte Variante der Ausführungsform nach 4;
• 5 einen Schnitt durch ein Fensterprofil nach einer fünften Ausführungsform der Erfindung ähnlich der ersten Ausführungsform der Erfindung;
• 6 einen Schnitt durch ein Fensterprofil nach einer sechsten Ausführungsform der Erfindung unter Verwendung eines Blendrahmens und Flügelrahmens aus Holz oder Hartschaum;
• 7 einen Schnitt durch ein Fensterprofil nach einer siebten Ausführungsform der Erfindung unter Verwendung eines Blendrahmens und Flügelrahmens aus Holz oder Hartschaum;
• 7a eine abgewandelte Variante der Ausführungsform nach 7;
• 8 eine achte Ausführungsform der Erfindung ähnlich zu der Ausführungsform nach 3, jedoch unter Verwendung eines Flügelrahmens und Blendrahmens aus Holz oder Hartschaum;
• 9 eine neunte Ausführungsform der Erfindung ähnlich zu der Ausführungsform nach 4, jedoch unter Verwendung eines Flügelrahmens und Blendrahmens aus Holz oder Hartschaum;
• 10 eine zehnte Ausführungsform der Erfindung ähnlich der Ausführungsform nach 9, jedoch ohne ein außenseitig angeordnetes Dämmelement unterhalb der Außendichtung;
• 11 eine elfte Ausführungsform der Erfindung ähnlich zu der Ausführungsform nach 10, ebenfalls ohne ein außenseitig angeordnetes Dämmelement unterhalb der Außendichtung; und
• 12 eine zwölfte Ausführungsform der Erfindung ähnlich der Ausführungsform nach 7.

In the following drawings, the invention is explained purely by way of example using several variants of a frame construction using the example of an openable window. Show:

• 1 a section through a window profile according to a first embodiment of the invention;
• 2 a section through a window profile according to a second embodiment of the invention;
• 2a a modified variant of the embodiment according to 2 ;
• 3 a section through a window profile according to a third embodiment of the invention;
• 4th a section through a window profile according to a fourth embodiment of the invention;
• 4a a modified variant of the embodiment according to 4th ;
• 5 a section through a window profile according to a fifth embodiment of the invention similar to the first embodiment of the invention;
• 6th a section through a window profile according to a sixth embodiment of the invention using a window frame and casement made of wood or rigid foam;
• 7th a section through a window profile according to a seventh embodiment of the invention using a window frame and casement made of wood or rigid foam;
• 7a a modified variant of the embodiment according to 7th ;
• 8th an eighth embodiment of the invention similar to the embodiment according to FIG 3 , but using a casement and window frame made of wood or hard foam;
• 9 a ninth embodiment of the invention similar to the embodiment according to 4th , but using a casement and window frame made of wood or hard foam;
• 10 a tenth embodiment of the invention similar to the embodiment according to 9 but without an externally arranged insulating element underneath the outer seal;
• 11 an eleventh embodiment of the invention similar to the embodiment according to FIG 10 , also without an externally arranged insulating element below the outer seal; and
• 12th a twelfth embodiment of the invention similar to the embodiment according to 7th .

Description of the preferred embodiments

The following figures show various examples of how vacuum insulating glass units can be integrated in a frame construction for a window, a door or a fixed glazing with frame profiles with low thermal conductivity.

The hollow profiles according to the 1 to 5 do not show the stiffening elements usually required inside these cross-sections produced either by pultrusion (applies to GFRP and CFRP) or extrusion (applies to all thermoplastics).

In 1 a section through a frame structure for a window or a door is shown, which has a vacuum insulating glass unit 1 owns. The vacuum insulating glass unit 1 is designed in a conventional manner. The vacuum insulating glass unit 1 is with the help of a gluing 7th on a wing profile 2 attached. Both the wing profile 2 as well as the frame profile 3 are profiles that are extruded or pultruded from plastic. In particular, come for the wing profile 2 as well as the frame profile 3 thermoplastics, in particular PVC, PP or PA, but also pultruded plastics such as GRP or CFRP are used.

The vacuum insulating glass unit 1 is made by a circumferential elastomer profile 9 fixed in position, which may also have glazing approaches in some areas. In the usual way there is between the bond 7th and the log 9 a backfill tape 8th . There is an inner glazing seal on the inside of the room 6th provided, while on the outside an outer seal 4th is provided.

In order to reduce the linear heat transfer coefficient in the area of the glass inset, there is also the frame profile 3 a heat-insulating foam in the area of the glass insert 12th intended. Between the frame profile 3 and the wing profile 2 is also an inner stop seal 11 intended.

To reduce the risk of condensation forming, there is a stop on the room side 5 provided, which represents a thermal coupling element and consists of a material whose thermal conductivity is at least by the factor 10 , preferably by the factor 20th is higher than the thermal conductivity of the plastic material of the wing profile 2 . If a material with particularly high thermal conductivity is desired, the stop, for example 5 consist of aluminum.

By providing the aluminum element 5 the area of the inner seal is coupled with high thermal conductivity 6th in the transition between the glass inset and the free glass surface to the indoor climate, which at least reduces the risk of falling below the dew point there.

The frame profile forming the outer insulation area 3 is with a thin metal cover 30th covered. Aluminum is preferably used as the material for the metal cover. The metal cover 30th has a wall thickness in the range between 0.5mm and 3mm and preferably between 1mm and 2mm. The metal cover 30th improves the appearance and durability of the outer frame profile. However, it is important that the outer insulation area has the desired insulation function. Therefore the distance between the Metal cover and the glass surface of the vacuum insulating glass unit at least 2mm and preferably at least 3mm, so that there is no undesired thermal coupling between the metal cover and the vacuum insulating glass unit in the outside area. If a distance of 5mm is provided between the metal cover and the vacuum insulating glass unit, the condensation on the room side is caused by the metal profile 30th hardly influenced in the area of the outer insulation area. A distance of 5mm is particularly preferred because this distance is the standard thickness of many commercially available outer sealing profiles 4th corresponds.

In addition to the in 1 The embodiment shown can be the hollow chambers of the wing profile 2 as well as the frame profile 3 be filled with a heat-insulating foam, as in 5 is shown.

In addition, the provision of the heat-insulating foam 12th be waived.

The embodiment according to 2 is similar to the one after 1 and can in principle in the same variants with regard to foaming with heat-insulating plastic and omitting the heat-insulating foam 12th be designed. In contrast to the embodiment according to 1 the stop is designed differently on the inside. The attack 5 inside is integral with the wing profile 2 educated. In addition, there is a thermal coupling element 15th provided, which is designed in the form of a metal insert in the cavity. The design according to 2 possesses over those after 1 in particular an advantage with regard to the visual design, since no separate glazing bead is provided on the inside of the room, which also requires special measures when painting. The metal insert 15th has the advantage that it is located inside a cavity of the wing profile 2 is located, the wing profile is also stiffened in the fastening area of the vacuum insulating glass unit and also serves as a thermal coupling element, since the heat transported through the relatively thin outer wall of the wing profile with the help of the highly heat-conducting metal insert 15th in the area of the inner seal 6th as well as the bonding 7th is transported.

2a FIG. 4 shows a modified embodiment similar to that of FIG 2 . The metal insert in the cavity serves as a coupling element 5 , but extends with a rib 24 through an opening 21st in the wing profile 2 out of the cavity and in the direction of the vacuum insulating glass unit 1 that the coupling element does not touch, however, so that there is a gap 23 between the coupling element 5 and the vacuum insulating glass unit 1 within the bond 7th consists. The thickness of the gap 23 can be about 1mm.

The design according to 3 shows a slightly different design of the sash 2 as well as the frame 3 , which is why next to the stop seal 11 inside also a stop seal 10 provided outside. However, the different design of the sash profile and frame profile is irrelevant for understanding the invention. In contrast to the configurations according to 1 and 2 becomes the vacuum insulating glass unit 1 jammed between the outer seal 4th as well as the inner seal 6th held, with an insulating element in the form of a heat-insulating foam on the outside 12th is provided. On the glazing bead 5 is in the embodiment according to 3 a thermal coupling element 15th Applied in the form of an aluminum foil, so that a thermal coupling of the surface of the vacuum insulating glass unit facing the inside 1 arises in the area of the glass inset.

The design according to 4th differs from the one after 3 merely to the effect that the glazing bead 5 completely the thermal coupling element 15th represents, since this is made of metal and preferably aluminum. The outer insulation area is created by the sash profile 2 formed, as based on the 1 with a metal cover 30th is covered. In addition, there is also the outside of the frame profile 3 with a second metal cover 32 similar to the metal cover 30th covered. The metal cover 30th extends over the sash profile 2 out to a distance d of 5mm to the vacuum insulating glass unit 1 . This design with a metal cover that extends beyond the frame profile forming the outer insulating area is possible in all of the illustrated embodiments.

In the 4a illustrated embodiment differs from that according to 4th by the additional provision of a spring element 22nd made of metal, which is preferably made in one piece with the coupling element 5 is formed and resilient on the vacuum insulating glass unit 1 is applied. It is important to ensure that the spring element 22nd is sufficiently flexible to be resilient to the vacuum insulating glass unit 1 but not to damage it. The coupling element is preferably made of aluminum.

Even with the configurations 3 , 4th and 4a, the cavities of the sash profile and the frame profile can be filled with a heat-insulating foam in order to further improve the overall heat insulation.

In the design according to 5 an example is shown in which the cavities of the airfoil 2 as well as the frame profile 3 with heat-insulating foam 16 are filled with foam. In addition, there is also the cavity between the glass strip made of metal 5 and the wing profile 2 with foam 17th filled out. By providing the insulating element 12th made of heat-insulating foam on the outside as well as the foam 17th on the inside, the linear heat transfer coefficient of the respective profile is further reduced, but at the same time by the provision of the glazing bead 5 The thermal coupling according to the invention to the indoor climate is ensured from metal with good heat conductivity. In the same way it is also possible to use the embodiment according to 5 Manufacture from profiles made of integral foam.

The embodiment according to 6th differs from that after 5 only to the effect that both the sash profile and the frame profile are made of wood or rigid foam or a composite of these materials. In this way, the thermal properties of a like in 5 Achieve shown profile with foamed plastic hollow profiles for the sash profile and frame profile in the same way. With a suitable selection of a rigid foam, additional thermal advantages can even be achieved compared to the previous configurations.

The design according to 6th however, again has the disadvantage that the metal stop is visible on the inside of the room and may also require special expertise in painting. This problem can be solved by using a 7th solve the embodiment shown, in which a metal insert in the area of the stop inside 15th is provided in wood or hard foam, which is the thermal coupling element 15th represents according to the invention. By, as in 7th is shown, the thermal coupling element 15th Over a larger part of the distance between the inside of the glass and the room-side closure of the sash profile 2 extends, the heat transport resistance is from the inside of the room in the direction of the vacuum insulating glass unit 1 significantly reduced in the area of the glass inset. The solution after the 7th has the advantage that, for example in the case of the wing profile being designed from wood, the thermal coupling element provided according to the invention 15th visually invisible.

The embodiment according to 7a improves the thermal coupling compared to the embodiment according to 7th in that in the area of bonding 7th a separate coupling spring 25th , in the embodiment according to 7a in the form of a U-shaped profile made of aluminum, which is elastic on both the coupling element 15th as well as the vacuum insulating glass unit 1 is applied and the heat conduction to vacuum insulating glass unit compared to the configuration according to 7th further improved. Alternatively, an integral part of the coupling element could also be used 15th connected spring element as in 4a shown instead of the separate U-shaped profile.

This concept can also be implemented with a hollow profile made of plastic, as shown in the 1 to 5 is shown as an example.

In the embodiment according to 8th are also a sash profile 13th made of wood or hard foam as well as a frame profile 14th made of wood or hard foam, each with a metal profile as a metal cover 30th , 32 used. The glazing bead attached to the sash profile via a tongue and groove connection 5 is also made of wood or rigid foam and has a thermal coupling element 15th in the form of a on the glazing bead 5 applied metal layer. For the thermal coupling element after 8th it can for example be an aluminum foil.

Even in the embodiments according to 6th to 8th as well as the following 9 can be on the outside of the vacuum insulating glass unit 1 provided thermal insulating foam 12th omitted, especially since the insulating effect of the air layer is still present there.

The embodiment according to 9 essentially corresponds to the one after 4th and differs from this in that instead of that in the embodiment according to 4th Profiles designed as a hollow profile 2 and 3 in the embodiment according to 9 the wing profile consists of solid material and is made of wood or rigid foam. The same applies to the frame profile 14th to.

In the 10 and 11 are exemplary based on the embodiments already described above according to the 7th and 9 the insulation elements arranged on the outside 12th not provided. Continue to show 10 and 11 the advantageous geometric dimensions realized in all embodiments based on the in the 10 and 11 marked relative dimensions for the insulation material thickness outside S1, the inside gasket thickness S2 and the glass inset S3.

For the glass inset S3 it has been shown to be particularly advantageous if it is selected between 15mm and 25mm. Too high a glass inset is negative in terms of the required frame width, which should not be too large for reasons of design and incidence of light. In addition, a high glass inset is also negative in terms of the overall thermal insulation of the window, since the frame is always less thermally insulating than the undisturbed vacuum insulating glass surface.

Too little glass inset should be avoided, since if the glass inset is too small, the problems of falling below the dew point of the surface temperature in the transition between the frame profile and the vacuum insulating glass unit occur even more clearly.

Furthermore, it is advantageous if the inner seal thickness S2 is selected to be small, since an inner seal with relatively good thermal insulation, especially in those configurations in which the vacuum insulating glass unit is between an outer seal 4 and an inner seal 6th is clamped, represents a series-connected heat transport resistance, which reduces the desired effect of the thermal coupling element. The smaller the inner gasket thickness S2, the more effective the thermal coupling element, since the heat flow made possible by this only has a lower resistance in the form of the inner glazing gasket 6th before it reaches the area of the vacuum insulating glass unit, which is particularly critical in terms of a possible dropping below the dew point. However, the inner seal thickness S2 should not be too small either, since if the inner seal thickness is too small, below about 2mm, the glass pane is mounted too hard on the inner stop and the necessary tolerance compensation can no longer be guaranteed. If an adhesive bond is provided in addition to the inner sealing strip, an inner seal thickness that is too small, corresponding to the adhesive thickness, cannot be selected because adhesive bonds that are too thin are no longer able to absorb temperature-related expansions without the bond breaking due to shear .

Finally, the insulation thickness outside S1 must be significantly greater than the inside seal thickness S2. A ratio S1 / S2> 3 and preferably> 4 is required in order to be able to use a vacuum insulating glass unit in the frame construction according to the invention.

All of the preceding embodiments have in common that a thermal coupling element is provided, which is provided in the frame construction according to the invention on the room side and in the area of the glass insert and which serves to transport a targeted heat transport from the room atmosphere to the area that is critical for a possible dew point undershoot is in the transition area between the glass inset and the inside glass surface of the vacuum insulating glass unit.

Claims (10)

Frame construction for a window, door or fixed glazing, comprising: - a frame profile (2, 3), the material of which has a thermal conductivity of less than 1.0 W / mK and - comprises a sash frame (2) and - a window frame (3); - A vacuum insulating glass unit (1) held in a glass inset (S3) of the frame construction; wherein - the vacuum insulating glass unit (1) has a heat transfer coefficient Ug of at most 1.0 W / (m ² K); characterized in that - the frame structure has a metal cover (30) on the outside of an outer insulating area, the wall thickness of which is in the range between 0.5mm and 3mm and the distance from the vacuum insulating glass unit (1) is at least 2mm and preferably at least 3mm. - The frame construction on the room side in the area of the glass inset comprises a thermal coupling element (5; 15) with a thermal conductivity that is increased by at least a factor of 10 and preferably by a factor of 20 and particularly preferably by a factor of 300 compared to the material of the frame profile of the sash frame (2) Thermal conductivity; and - an outer insulation thickness (S1) of the outer insulation area in the heat flow direction is at least a factor of 3, preferably at least a factor of 4, greater than the thickness (S2) of an inner seal (6). Frame construction according to Claim 1 , wherein the frame construction has a stop on the room side, which is provided in the form of a glass strip (5) or a fixed stop, the stop on the room side comprising the thermal coupling element (15). Frame construction according to Claim 1 or 2 , the frame profile of the sash frame (2) made of wood, rigid integral foam, GRP, CFRP or thermoplastic, in particular PVC, PP or PA, or a composite profile made of wood and rigid foam or a composite profile made of a thermoplastic and rigid foam. Frame construction according to one of the preceding claims, characterized in that the glass inset (S3) of the vacuum insulating glass unit (1) is between 15mm and 25mm. Frame construction according to any one of the preceding claims, further comprising a Insulating element (12) which is arranged on the outside in the area of the glass insert of the vacuum insulating glass unit (1). Frame construction according to one of the preceding claims, characterized in that the thermal coupling element (5) comprises metal at least in some areas and is preferably a glass strip (5) made of aluminum. Frame construction according to one of the Claims 1 to 5 , characterized in that the thermal coupling element (15) is aluminum foil with which the glass strip or the stop (5) is covered. Frame construction according to one of the preceding claims, characterized in that the thickness of an outer seal (4) in the heat flow direction is at least 50% greater than the thickness of an inner seal (6). Frame construction according to one of the preceding claims, characterized in that the metal cover (30) consists of aluminum. Building envelope comprising a frame construction according to one of the preceding claims.

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