DE102007018305A1 - Profile frame construction with reduced linear heat transfer coefficient - Google Patents

Abstract

A profile frame construction comprises a base profile (12) made of metal, which is integrally formed with a base frame profile (10) or is mounted on a base frame profile (10) made of wood or metal. Ausfachungselemente (20; 40) are applied to inner seal strips (18) which are fixed to the base profile (12). The profile frame construction is characterized in that the inner seal strips (18) have a width (B) of at least 5 mm and a height (H) of at least 3 mm and the material of the inner seal strips has a W / mK according to standard. The infill elements (20; 40) may comprise at least one multi-pane insulating glass (20) or comprise at least one panel. In the case of a multi-pane insulating glass, this spacer (32) has a warm edge and a total thickness (D) of at least 24 mm. In the case of a panel, this covers shells as well as an insulating core whose thermal conductivity lambda <SUB> K </ SUB> <= 0.05 W / mK. The spacers (46, 48) have a width between 10 mm and 30 mm and a thermal conductivity of lambda <SUB> A </ SUB> <= 0.15 W / mK, preferably lambda <SUB> A </ SUB> < = 0.08 W / mK, more preferably lambda <SUB> A </ SUB> <= 0.04 W / mK and most preferably lambda <SUB> A </ SUB> <= 0.03 W / mK. The profile frame construction has a heat transfer coefficient U <SUB> f </ SUB> of the profile of at most 2.5 W / m <SUP> 2 </ SUP> K and a linear heat transfer coefficient Psi of the infill element in the profile, which is 0.08 W / mK does not exceed.

Description

Field of the invention

The The invention relates to a profile frame construction with the features of the preamble of claim 1 and claim 6. Such Profile frame construction comprises a basic metal profile, the is integrally formed with a base frame profile or attached to a base frame profile of wood or metal, Ausfachungselemente that rest against the inner profile attached to the inner seal strips.

such Profile frame constructions are used in facade construction, but also in general for thermally insulated frames and infills made of insulating glass panes and panels used in windows and doors.

State of the art

Under the growing pressure for ever more efficient and gentler handling with energy resources also wins the thermal engineering Optimization of profile frame constructions increasingly important. Solutions in the state of the art are here in particular in that an attempt is made to assign individual elements optimize, but without taking into account the entire profile frame construction.

So exist in the prior art proposals, insulating glass panes or panels with particularly low heat transfer coefficients to develop. In the same way there are concepts for reduction the heat losses in the frame area, d. H. in the fold area between adjacent infill elements. Also the clamping area of panels and glass panels is in terms of heat loss particularly critical, which is why reinforced in future standards on the linear heat transfer coefficient ψ (the linear or length-related heat transfer coefficient due to the combined thermal effect of infill elements with the profiles) is turned off. Values of ψ are for example in tabular form.

Just the consideration of all in a profile frame construction existing components and their contribution to heat loss but can lead to a satisfactory overall concept. For example, it is absurd as infilling elements of a profile frame construction Use vacuum insulation panels, but at the same time high length related Allow passage coefficients in the fold area. So is in solutions in the prior art to observe that the thermo-technical consideration the joint area between adjacent Ausfachungselementen opposite Often the design of infill elements itself is neglected becomes.

Presentation of the invention

Of the Invention is based on the object, in the context of an overall view and coordination of individual measures the thermotechnical Optimize behavior of profile frame designs.

These Task is by a profile frame construction with the features of claim 1 or claim 6.

A profile frame construction according to the invention comprises a base profile made of metal, which is formed integrally with a base frame profile or is fastened on a base frame profile made of wood or metal. In other words, a one-piece metal base profile may be present, such as extruded from aluminum, for example, or roll formed from stainless steel. Alternatively, it is also possible to provide a base profile made of metal separately from a base frame profile and in this way to realize known types of profile frame constructions, such as wood-aluminum constructions or steel-steel constructions. The profile frame construction further comprises infilling elements, which rest against inner sealing strips which are fastened to the base profile. Furthermore, an optional pressure bar clamps the infill elements against the inner sealing strips. Such a conventional profile frame construction is now optimized with respect to the thermal performance in that the inner seal strips have a width of at least 5 mm and a height of at least 3 mm and the material of the inner seal strips a thermal conductivity of λ _D ≤ 0.25 W / mK according to standard specification. According to a variant of the invention, the infilling elements comprise at least one multi-pane insulating glass, the multi-pane insulating glass spacers having a warm edge and a total thickness of at least 24 mm. Furthermore, the heat transfer coefficient U _{f of} the profile U _f ≤ 2.5 W / m ² K, whereby a linear heat transfer coefficient ψ can be achieved, which does not exceed the value of ψ = 0.08 W / mK. According to a second alternative solution, the infill elements comprise at least one panel with cover shells and a Dämmkern whose thermal conductivity λ _K ≤ 0.05 W / mK, and spacers with a width of at least 10 mm and at most 30 mm and with a thermal conductivity λ _A of λ _A ≤ 0.15 W / mK preferably λ _A ≤ 0.08 W / mK, more preferably λ _A ≤ 0.04 W / mK, and most preferably λ _A ≤ 0.03 W / mK. The above-mentioned heat transfer coefficient U _{f of} the profile is U _f ≦ 2.5 W / m ² K. This makes it possible to achieve a linear heat transfer coefficient ψ of ≦ 0.08 W / mK.

The Geometry and the material used by inner sealing strips has always been only in terms of their sealing function and a sufficient elasticity selected. In an overall view in terms of thermo-technical Behavior of the overall construction were but inner sealing strips not included. By the inner seal strips a width of At least 5 mm, a barrier between the basic profile and the infill elements that are material to a reduction the loss of heat flow in the edge region of the infilling leads. This measure is directly related to Multi-pane insulating glass used spacers with warm edge or the spacer used in the case of panels with a Width between 10 mm and 30 mm and with the claimed thermal conductivity.

The claimed profile frame design takes into account the thermal interaction between the frame construction and the Infill elements, paying special attention to heat loss in the edge region of the infilling elements in cooperation with the Profiles and thus the length-related heat transfer coefficient ψ laid becomes. In this way, not only the heat flow on Fold between the infill elements, d. H. at the fugue between the but with panels or glass elements provided surfaces in particular, the heat flow in the edge region of the infilling elements involved in an overall concept. At the same time it will be ensured that also the infilling elements themselves a good insulation effect have, prescribed by the invention is that it is either at the Ausfachungselementen to a multi-pane insulating glass or around a panel with a Dämmkern with given maximum thermal conductivity is.

Further Measures to improve the thermotechnical Behavior of the profile frame construction follow from the rest Claims.

To a preferred embodiment is at least one glass sheet of the multi-pane insulating glass on a main surface with a coating with low emissivity provided. For facade constructions this main surface is usually chosen so that she points to the inside of the building and thus the heat loss reduced by heat radiation through the multi-pane insulating glass.

If the multi-pane insulating glass is a Zweiperibenisolierglas is the total thickness of the glass sheet preferably at least 24 mm. On this way, you can have a more in-between space realize as 12 mm, which in particular in the area of the edge bond with warm edge a low heat loss current follows.

If the multi-pane insulating glass comprises three glass panes, is the total thickness of the multi-pane insulating glass element is at least 36 mm. This measurement also ensures that conventional Single glass elements of the disc space larger than 12 mm and preferably in the range between 14 mm and 20 mm.

Preferably The spacer with warm edge is made of plastic material. Under the technically common term "spacer with warm edge "are also thin stainless steel profiles, but own Spacer made of plastic material has an improved insulating effect, so that too, this measure will improve the overall thermo-technical behavior leads.

Provided the infill elements of the invention Profile frame construction include at least one panel is the Insulating core preferably designed so that it preferably Mineral fiber, and more preferably a vacuum insulation panel includes. According to an alternative, preferred embodiment the insulating core can also be foamed and persists preferably made of PUR or PS foam. The insulating core can also have a multi-layered structure and, for example, a Include mineral fiber layer.

A particularly preferred embodiment of a panel has an insulating core of microporous, inorganic silicate substances. Such a product is sold, for example, under the brand name WDS ^® Vacupanel and has a particularly low thermal conductivity at high Evakuierungsgraden.

To a particularly preferred embodiment of the invention is the flameproof spacer of the type constructed like a vacuum insulation panel, but without evacuation. This measure has a surprising high effect on the result of the overall optimization of the linear heat transfer coefficient and allows values of ψ ≤ 0.01 W / mK at appropriate To reach Dämmkernen. This contrasts with a significant improvement the default value of λ ≤ 0.08 W / mK.

According to a preferred embodiment of the invention, the inner sealing strips are designed in one piece for a glass fold. In this way, a barrier between the base profile and the pressure bar is made. Improved drainage or condensing water drainage properties are also present and are of no interest here the measures according to the preferred embodiments of the invention all serve to improve the thermal performance of profile frame structures.

A further measure to improve the thermotechnical Behavior is to use the inner sealing strips with at least To provide a cavity in the cross-sectional geometry. These Measure can also serve the elasticity to increase the inner sealing strip and thus more leeway with regard to the selection of a material with low thermal conductivity to offer. According to a preferred embodiment of the invention the profile frame construction further comprises a pressure bar made of aluminum or an aluminum alloy with a smooth surface. Smooth surface aluminum reflects infrared radiation very good and is therefore suitable for heat loss through radiation low in the joint area between adjacent infill elements to keep.

Preferably The profile frame construction further includes outer sealing strips between pressure bar and the infill elements, wherein the outer sealing strips have a width of at least 5 mm. From a technical perspective the outer seals can be configured as desired and even through a so-called structural sealing + glazing are replaced, but are external seals with a width of over 5 mm and of a material with a thermal conductivity of not more than 0.25 W / mK in accordance with the standard the occurring in the edge region of the multi-pane insulating glass or panel Loss heat flow downstream of another resistor.

To a particular preferred embodiment of the invention the profile frame construction further comprises an insulating element, preferably made of foamed material, on, which is in extends the glazing rebate area between adjacent infill elements. By such an insulating element can as complementary Measure both the heat flow from the basic profile towards the pressure bar, as well as heat losses from the infill elements can be reduced into the glass fold by both heat conduction as well as convection effects are reduced.

in the Interaction with external sealing strips lies the insulating element preferably at this. This way becomes the outside the profile frame construction out, in facade constructions for Weather side, a complete sealing of the joint area hin causes. From a thermo technical point of view are also small gap between the insulating element and the outer sealing strips acceptable and may have the added benefit possess that removing moisture in Glasfalzbereich is relieved.

If the infill elements comprise at least one multi-pane insulating glass, is preferably the insulating element of the spacer (s) spaced between the glass panes of the multi-pane insulating glass. This measure serves the targeted removal of moisture in Glasfalzbereich to facilitate. However, the insulating element on the Close the front side of the outer glass tight and on this Way heat losses in Glasfalzbereich possible largely reduce.

in the Case of a one-piece design of the inner sealing strips the insulating element is preferably located on the inner sealing strip at. In this way, the entire Glasfalzbereich with an optimal Isolated on the geometry matched insulating element.

The inventive profile frame construction is preferably as part of a facade or as part of a window or a door used.

The optimized profile frame construction according to the invention For the first time next to the infill elements also the inner sealing strips along with the spacers of the infill elements, the one have an unexpectedly high influence on the linear heat transfer coefficient ψ, such as numerical calculations and experiments have revealed.

Brief description of the figures

following the invention is purely exemplary by way of the attached Drawings described in which

1 a horizontal section through a wood-aluminum profile frame construction according to the invention represents;

2 shows a horizontal section through a steel-aluminum profile frame construction according to the invention;

3 shows a horizontal section through an inventive wood-aluminum profile frame construction with different Ausfachungselementen; and

4 represents a further variant of a wood-aluminum profile frame construction with different Ausfachungselementen.

Ways to execute the invention

In the description below the same components are each designated by the same reference numerals. In the 1 shown profile frame construction shows the Glasfalzbereich with adjacent Ausfachungselementen a post profile of a facade construction. The base frame profile 10 is made of wood, on which a basic profile 12 is extruded from extruded aluminum. The basic profile 12 has a screw channel 14 as well as fastening approaches 16 for inner sealing strips. On the attachment approaches 16 is an inner seal 18 fitted, which is made in one piece in the present embodiment, that is, the two sub-areas, the elastic to the infill elements 20 abutment are integrally connected to each other and are in contact with the screw 14 and beyond its exterior facing towards the facade openings. The inner sealing strips 18 are with a cavity 22 to improve the thermal insulation and with arranged in stepped heights incisions 24 provided, which serve to reduce the inner sealing strip for overlapping arrangement in the attachment area between posts and bars to a desired height. Alternatively, the cuts serve 24 to be able to provide a filling thickness compensation of the inner sealing strips.

The dimensions of the inner sealing strips are made 1 not quantifiable, but they have according to the invention a width B of at least 5 mm and a height H of more than 3 mm. The sealing strips 18 are made of a suitable material whose thermal conductivity does not exceed λ = 0.25 W / mK in accordance with the standard.

The infill elements are facades outside of outer sealing strips 26 held in suitable receiving geometries in the pressure bar 28 are introduced. The pressure bar 28 is made with the help of spaced mounting screws 30 in the screw 14 fixed to over the pressure bar 28 and the intermediate external seals 26 the infill elements 20 against the basic profile 12 to fix.

In the embodiment according to 1 the infill elements are triple insulating glasses, with the interpane space d between the individual glasses 20a . 20b and 20c is greater than 8 mm and preferably in the range between 14 mm and 20 mm. Thus, the triple insulating glass has a total thickness D of at least 32 mm, preferably ≥ 36 mm, more preferably ≥ 40 mm, and most preferably ≥ 44 mm or ≥ 48 mm.

What is essential is that between the individual slices 20a . 20b and 20c of the multi-pane insulating glass spacers 32 according to the "warm edge" type prEN 13947: 2006 are and preferably have plastic spacers.

In Glasfalzbereich between the adjacent Mehrscheibenisoliergläsern is a Dämmkörper 34 , which consists of a foamed material with low thermal conductivity and according to the illustrated embodiment is shaped so that it both at the two outer seals 26 as well as on the mutually facing end faces of the glass 20c elastically applied. Furthermore, the insulating body extends 34 between the pressure bar 28 and the one-piece inner gasket 18 in the area in which this over the screw 14 is laid. Only in the area of spacers 32 and optionally the mutually facing end faces of the glass elements 20a , and 20b the insulating body is spaced from these.

In the 1 illustrated technical solution can lead to a heat transfer coefficient U _{f of} the profile of U _f ≤ 0.7 W / m ² K depending on the thickness of the filling element.

In the 2 also shown profile frame construction can also achieve a heat transfer coefficient of the profile of U _f ≤ 0.7 W / m ² K, but due to the provision of a base frame profile 10 made of steel more action is needed to achieve this. The multi-pane insulating glass elements 20 correspond to those according to 1 , The same applies to the pressure bar 28 , the attachment by facade screws 30 as well as the shape of the outer sealing strips 26 ,

Differences from the embodiment according to 1 arise in the shape of the basic profile 12 whose screw is shorter and the no in 1 illustrated relief groove 13 for moisture relief of the base frame profile made of wood. Accordingly, the one-piece running inner seal 18 designed differently, as well as this so on the basic profile 12 is agreed that the connection area between the individual sealing areas on the screw 14 rests and extends precisely over its directed towards the facade outside opening.

The insulating body 34 is different to that 1 Shaped formed by also on the front sides of the facing glass sheets 20a rests and in this way the Glasfalzbereich completely seals. Only in the area of spacers 32 , which according to the embodiment according to 1 are formed as a warm edge, is the insulating element 34 recessed to allow a moisture removal. By the shape of the Dämmelements 34 especially with regard to the tight contact with the glass panes 20a can also be found in the 2 shown Facade construction with a base frame profile made of metal and with a corresponding thickness of the infill element, here at least 48 mm, the very low heat transfer coefficient U _f of ≤ 0.7 W / m ² K realize.

In the 3 illustrated embodiment is substantially identical to that according to 1 , Therefore, the description of the individual components can be dispensed with. The main difference is that in addition to a multi-pane insulating glass 20 as a infill element a panel is used. The panel 40 is a vacuum insulation panel with a total heat transfer coefficient averaged over the surface of the panel between 0.1 W / m ² K and 0.3 W / m ² K. The vacuum insulation panel consists of a glass element arranged on the outside of the facade 42 as well as a facade facing the inside of the cover 44 made of metal, in particular aluminum, steel, stainless steel, copper or plastic or wood, between which the evacuated area 45 a conventional vacuum insulation board is located. The key is that a spacer 46 whose width varies between 10 mm and 30 mm and whose height is at least 16 mm. The spacer is selected so that it has a low thermal conductivity, which, depending on the selection of a suitable spacer in the range of λ = 0.15 W / mK, λ = 0.10 W / mK, λ = 0.08 W / mK , or even in areas of thermal conductivity of 0.06, 0.04 can move up to 0.02 W / mK. The best results are achieved with spacers that are constructed similar to a vacuum insulation panel, but which is not evacuated. Depending on the design of the panel can be another spacer 48 be provided, which compensates only as a spacer the different thicknesses of the panel and the multi-pane insulating glass, for which, however, the same selection criteria apply as for the spacer 46 ,

Alternatively, in the case of 3 remaining free space, directed towards the façade inside behind the cover shell 44 fill out. A corresponding representation can be found in 4 with regard to all other elements such as basic frame profile 10 , Basic profile 12 , Inner gasket 18 , Multi-pane insulating glass 20 , Outer sealing strips 26 , Pressure bar 28 , Facade screws 30 and insulating element 34 identical to the embodiments according to 1 and 3 is. The difference of the embodiment according to 4 is that here the panel has an inside cover shell 44 according to the cover shell 3 , an adjoining vacuum insulation board with the insulating core 45 and another layer of insulation 50 has, before facades outside again an outer cover shell, here in the form of a glass element 42 , is provided. Notwithstanding the embodiment according to 3 is a single spacer 46 for which the same requirements apply with regard to the width range and the graduated, technically realizable values for the thermal conductivity as for the spacer described above 46 to 3 , The panel thus has a thickness which corresponds to that of the 3-fold insulating glass.

The graduated areas for the spacers after 3 and 4 were chosen to be especially in terms of constructions like in 3 and 4 represented with Mehrscheibenisolierglaselementen and panels to perform the optimization of the invention can. The decisive variable to be optimized is the linear heat transfer coefficient ψ, which is a parameter for the clamping area between infill elements and frame profile. If panels are provided in a profile frame construction, a suitable choice of highly effective insulating cores and highly effective spacers allows linear heat transfer coefficients of at most ψ = 0.08 W / mK, but also 0.06, 0.04, 0.02 or even only 0, Realize 01 W / mK. This represents a significantly improved value compared to the linear heat transfer coefficients achievable with multi-pane insulating glass of ψ ≦ 0.08 for double insulating glass and ψ ≦ 0.07 for triple insulating glass. However, it is not sensible to carry out only individual optimization measures, which is crucial, as already explained in detail above was to keep an eye on the overall concept and coordinate the individual components.

New building regulations will further tighten the requirements for thermal insulation of profile frame constructions and especially facades. Here, the demands increase with increasing number of storeys, increasing area and especially in air-conditioned rooms. Only by coordinating a bundle of measures, namely the use of infill elements with low heat transfer coefficients and an optimization of the inner sealing strips, but above all by optimizing the edge regions of both insulating glass and panels can be obtained linear heat transfer coefficients, well below the values in the Preliminary standard prEN 13947: 2006 lie.

Remarkable is that the way especially trodden in the professional world, double heat protection glass to replace with triple insulating glass, generally significant less potential for improvement than a concentration to the above interacting factors, the the linear heat transfer coefficient of the infilling elements especially effective lowering.

The Spacer with warm edge for multi-pane insulating glass are preferably optimized so that the product Wall thickness d and thermal conductivity 0.0070 W / K does not exceed, preferably less than or equal to 0.0050 W / K and most preferably less than or equal to 0.0025 W / K.

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited non-patent literature

• - prEN 13947: 2006 [0037]
• - Preliminary standard prEN 13947: 2006 [0046]

Claims (21)

Profile frame construction comprising: - a basic profile ( 12 ) made of metal, integral with a base frame profile ( 10 ) or on a base frame profile ( 10 ) made of wood or metal; and infill elements ( 20 ; 40 ) attached to inner sealing strips ( 18 ), which are at the base profile ( 12 ) are attached; characterized in that - the inner sealing strips ( 18 ) have a width (B) of at least 5 mm and a height (H) of at least 3 mm; and - the material of the inner sealing strips has a thermal conductivity of λ _D ≤ 0.25 W / mK according to standard; - infill elements ( 20 ; 40 ) at least one multi-pane insulating glass ( 20 ), wherein the multi-pane insulating glass spacers ( 32 ) with warm edge; and - has a total thickness (D) of at least 24 mm; and - the heat transfer coefficient of the profile U _f ≤ 2.5 W / m ² K and the linear heat transfer coefficient ψ of the infill element in profile does not exceed the value of 0.08 W / mK. Profile frame construction according to claim 1, characterized in that at least one glass pane of the multi-pane insulating glass on a main surface with a coating of low Emissivity is provided. Profile frame construction according to claim 1 or claim 2, characterized in that the multi-pane insulating glass Two-pane insulating glass is and the total thickness (D) of the glass pane at least 24 mm. Profile frame construction according to one of claims 1 and 2, characterized in that the multi-pane insulating glass three glass sheets ( 20a . 20b . 20c ) and the total thickness of the multi-pane insulating glass (D) is at least 32 mm. Profile frame construction according to one of the preceding claims, characterized in that the spacer ( 32 ) with a warm edge made of plastic material. Profile frame construction comprising: - a basic profile ( 12 ) made of metal, integral with a base frame profile ( 10 ) or on a base frame profile ( 10 ) made of wood or metal; and infill elements ( 20 ; 40 ) attached to inner sealing strips ( 18 ), which are at the base profile ( 12 ) are attached; characterized in that - the inner sealing strips ( 18 ) have a width (B) of at least 5 mm and a height (H) of at least 3 mm; and - the material of the inner sealing strips has a thermal conductivity of λ _D ≤ 0.25 W / mK according to standard; - infill elements ( 20 ; 40 ) at least one panel ( 40 ) comprise with cover shells ( 42 . 44 ) as well as an insulating core ( 45 ), whose thermal conductivity λ _K ≤ 0.05 W / mK; and with - spacers ( 46 . 48 ) with a width between 10 mm and 30 mm and with a thermal conductivity λ _A of λ _A ≤ 0.15 W / mK, preferably λ _A ≤ 0.08 W / mK, particularly preferably λ _A ≤ 0.04 W / mK and most preferably λ _A ≤ 0.03 W / mK; and - the heat transfer coefficient U _{f of} the profile U _f ≤ 2.5 W / m ² K and the linear heat transfer coefficient ψ of the infill element in the profile does not exceed 0.08 W / mK. Profile frame construction according to claim 6, characterized in that the insulating core ( 45 ) comprises a vacuum insulation panel. Profile frame construction according to claim 6 or claim 7, characterized in that the insulating core a mineral fiber layer ( 50 ). Profile frame construction according to claim 6, characterized characterized in that the insulating core is foamed, preferably made of PUR or PS foam. Profile frame construction according to claim 6, characterized characterized in that the insulating core is made of microporous, inorganic silicate substances. Profile frame construction according to one of claims 6 to 9, characterized in that the spacer of the panel ( 46 . 48 ) corresponds structurally to a vacuum insulation panel without evacuation. Profile frame construction according to one of the preceding claims, characterized in that the inner sealing strips ( 18 ) are designed in one piece for a Glasfalz. Profile frame construction according to one of the preceding claims, characterized in that the inner sealing strips ( 18 ) at least one cavity ( 22 ) have in their cross-sectional geometry. Profile frame construction according to one of the preceding claims, further comprising a pressure strip ( 28 ) made of aluminum or an aluminum alloy with a smooth surface. Profile frame construction according to one of the preceding claims, further comprising outer sealing strips ( 26 ) between a pressure bar ( 28 ) and the infill elements ( 20 ; 40 ), wherein the outer sealing strips ( 26 ) have a width of at least 5 mm. Profile frame construction according to one of the preceding claims, further comprising an insulating element ( 34 preferably made of foamed material extending into the glazing rebate area between adjacent infill elements ( 20 ; 40 ). Profile frame construction according to claim 16, if dependent on claim 15, characterized in that the insulating element ( 34 ) on the outer sealing strip ( 26 ) is present. Profile frame construction according to claim 16 or claim 17, characterized in that the infill elements ( 20 ; 40 ) at least one multi-pane insulating glass ( 20 ), and the insulating element ( 34 ) of the spacer (s) ( 34 ) between the glass sheets ( 20a . 20b . 20c ) of the multi-pane insulating glass ( 20 ) is spaced. Profile frame construction according to one of claims 16 to 18, insofar as these are dependent on claim 12, characterized in that the insulating element ( 34 ) on the inner sealing strip ( 18 ) is present. Profile frame construction according to one of the preceding Claims, characterized in that this part of a Facade is. Profile frame construction according to one of the preceding Claims, characterized in that this part of a Window or a door is.