DE19832731A1 - Spacer profile for a spacer frame of an insulating pane unit - Google Patents

Abstract

A profiled spacer for the spacer frame of an insulating glass unit, whereby said profiled spacer is placed on the edge area of at least two interspaced sheets of glass and a gap is formed between both sheets. The body of the profiled spacer is made from a low heat-conductive material and is joined to a diffusion-tight layer that extends substantially along the entire length thereof. The invention is characterized in that the diffusion-tight layer has at least one area that extends in a longitudinal direction of the profiled spacer, whereby said area exhibits low thermal conductivity perpendicular to the longitudinal direction of the profiled spacer.

Description

The present invention relates to a spacer profile for a Spacer frame of an insulating pane unit, which in the edge area of at least two spaced disks to form one The space between the panes is to be attached, the profile body of the Spacer profile consists of poorly heat-conducting material and with a diffusion densities extending essentially over its entire width Layer of good heat-conducting material is connected.  

The washers of the insulating washer unit are within the scope of the invention normally panes of inorganic or organic glass without however, the invention would be limited to this. The panes can be coated or otherwise refined to make the insulating disc unit special To provide functions such as increased thermal insulation or sound insulation.

The profile body of the spacer profile made of poorly heat-conducting material comprises the volume of the main part of the spacer profile and gives it his cross-sectional profile.

Poorly heat-conducting materials are said to be within the scope of the invention be understood that clearly compared to metals, d. H. at least one Factor 10, show reduced thermal conductivity. The thermal conductivity values λ are typically on the order of 5 W / (m.K) and below are preferred it is less than 1 W / (m.K) and more preferably less than 0.3 W / (m.K). Plastics will generally fall under this definition.

The diffusion-tight layer normally becomes at least in some areas be cohesively connected to the profile body. With "cohesive connected "means that the profile body and the diffusion-tight layer are permanently connected to one another, for example by coextruding the Profile body with the diffusion-tight layer or through a separate Laminating the diffusion-tight layer, if necessary via an adhesive middle or like techniques.

Spacer frames have one of the most important tasks, the washers Insulating washer unit to keep the mechanical strength of the unit to ensure and the space between the panes from external influences protect. Especially with insulating pane units with high thermal insulation determine that the heat transfer characteristics of the edge bond and  thus the spacer frame or the spacer profile from which it is manufactured, requires special attention. A deterioration in Thermal insulation of an insulating pane unit in the edge area, in particular by Usual metallic spacers, has been used several times. Clearly visible the increased heat conduction is evident in the area of the edge bond Defrosting at the edge of the inner pane at low outside temperatures. It is generally sought to avoid such condensation low outside temperatures, the temperature in the edge area at the To keep the inner pane as high as possible. Developments in this direction are under the term "warm edge" techniques become known.

In addition to metallic spacer profiles, they have also been used for a long time Spacer profiles made of plastic are used for the low heat conduction of these Exploit materials. However, such materials usually have one low diffusion tightness compared to metal. At Spacer profiles made of plastic must therefore take special measures ensure that the air humidity in the area is not in the The space between the panes penetrates to such an extent that the absorption capacity of the desiccant usually housed in the spacer profiles soon is exhausted and the functionality of the insulating disc unit is impaired becomes. Furthermore, a spacer profile must also prevent filling gases from the Space between panes, such as argon, krypton, xenon, Sulfur hexafluoride, escape from this. Conversely, in the Outdoor ambient air does not contain nitrogen, oxygen, etc. in the Schei Enter the gas gap. So far in the following we speak of diffusion tightness is, this means both vapor diffusion tightness and gas diffusion tightness fit the gases mentioned.

To improve the vapor diffusion tightness, DE 33 02 659 A1 proposes was used to form the preamble of claim 1, before  Spacer profile made of plastic with a vapor diffusion-tight layer (Vapor barrier) by placing on the profile body made of plastic the side that faces away from the space between the panes when installed is a thin metal foil or a metallized plastic film is applied. This metal foil must fill the space between the panes as completely as possible span so that the desired vapor barrier effect occurs. The disadvantage here is however, that the metal foil has a path of high thermal conductivity Form the washer of the insulating washer unit to the other. The one through use a plastic as a profile material achieved effect of reducing the This significantly reduces the thermal conductivity of the edge bond.

To the disadvantage of the high thermal conductivity of the metallic components of To decrease spacer profiles, spacer profiles are made from bad thermally conductive material have been developed, in which the through the metal foil of one disk to the other formed path of high thermal conductivity is specifically extended has been. Such a spacer profile was named THERMOPLUS® TIS, for example, in the brochure "Impulses for the future" of Flachglas AG is presented and is in the older, not pre-published German Patent application 198 05 265.0 described. The plastic profile body of this Spacer profile includes a desiccant chamber for receiving hygroscopic materials, with contact bridges on both sides of the chamber Attachment are provided on the inside of the pane, which have over bridge sections the desiccant chamber are connected. On the in the installed state The outside of the pane facing away from the outside is the profile with one Corner bending simplifying reinforcement layer provided, which also for the Diffusion tightness ensures. The path formed by the diffusion-tight layer high heat conduction is significantly longer due to its meandering course than the width of the space between the panes. Depending on Profile geometry can be the length of a metal foil normally formed diffusion-proof layer up to four times the width of the  Washer space or more, whereby the heat conduction through the Spacer profile from one disc to another is significantly reduced.

Another spacer profile that has reduced heat transfer from one disk to another is sought in patent application WO 94/17260 A1 disclosed. The known spacer profile has one of two metallic Half-shells formed profile body, the two half-shells a core enclose from poorly heat-conducting material, in which a desiccant is embedded. The metallic half shells have one with metallic ones Spacers usual thickness and consist for example of high thermally conductive aluminum. The solid polymer core breaks through the metallic one Profile body both on the side facing the space between the panes and on the outside, so that the metallic half-shells there several millimeters are spaced from each other. The known spacer profile is not sufficiently diffusion-proof due to the design. Because of the relatively large Material thickness of its profile body made of highly heat-conducting aluminum its thermal engineering data are also unsatisfactory.

It is the object of the present invention to be inexpensive on a large scale producible spacer profile with a profile body made of bad heat-conducting material and a diffusion-proof layer place that is highly heat-insulating and at the same time sufficiently diffusion-tight.

This task is carried out by a spacer profile with the characteristics of Claim 1 solved.

According to the invention it is provided that the diffusion-tight layer has at least one area extending in the longitudinal direction of the spacer profile reduced heat conduction across the longitudinal direction of the spacer profile having.  

The area with reduced heat conduction means a section of the diffusion-tight Layer in which their heat conduction compared to their adjacent Sections is degraded.

The area with reduced heat conduction can be marked by a line Recess are formed which the diffusion-tight layer in its Thickness direction partially penetrated, for example in the form of a cross section about triangular notch.

According to a preferred embodiment, the area is reduced However, heat conduction is formed by a linear recess, which the diffusion-tight layer completely interrupts in its thickness direction. Hereby there is an immediate heat transfer between the to the recess adjacent ends of the diffusion-tight layer avoided.

It can also be provided that at least two parallel, from each other spaced line-shaped recesses in the diffusion-tight layer be formed.

The line-shaped recess of the diffusion-tight layer can be used as continuous continuous line (notch, slot) or as a series of perforations arranged in a line.

Surprisingly, it has been shown that there is a considerable reduction in heat conduction can already be achieved if the linear recess with a Width of only about 0.1 mm to 1 mm is executed. It was found be that a linear recess in the diffusion-tight layer in a such a small width even in the embodiment of the recess than that no interruption completely penetrating the diffusion-tight layer  significant reduction in the diffusion tightness of the spacer profile caused.

To improve the diffusion tightness, if necessary, can go further be provided, the linear recess with a bead from a fill in or cover diffusion-tight, poorly heat-conducting material. A suitable material for such a bead is a butyl sealant Isobutylene base, which is usually used to glue the spacer profile to the The inside of the pane of the insulating pane unit is used.

However, the area with reduced heat conduction can also be arranged a strip-shaped insert from another, opposite the material the diffusion-tight layer is less heat-conducting and also diffusion-tight Material can be formed in the diffusion-tight layer.

The area with reduced heat conduction can also be reduced by a physical or chemical modification of the diffusion-tight layer along a strip-shaped region are formed, for example by a region Oxidation, material removal or a porous treatment.

The diffusion-tight layer is preferably after that in the installed state outside surface of the profile body arranged or at least close to this partially embedded in the profile body.

The diffusion-tight layer preferably consists of one material, in particular a metal with a thermal conductivity λ ≦ 50 W / (m.K). Suitable materials are for example stainless steel or chromed or tinned iron sheet. The thickness of the diffusion-tight layer should be at least 0.02 mm.  

It is useful if the diffusion-tight layer is made of tinned iron sheet (Tinplate) or chromed iron sheet a thickness of less than 0.2 mm, preferably at most 0.13 mm, while with a diffusion-tight layer made of stainless steel a thickness of less than 0.1 mm, preferably at most 0.05 mm, is to be aimed for.

The poorly heat-conducting material of the profile body can be a thermoplastic Plastic with a thermal conductivity of λ <0.3 W / (m.K), such as polypropylene, Polyethylene terephthalate, polyamide or polycarbonate.

According to a particularly preferred embodiment, the profile body has a Hollow chamber to hold desiccant and is the diffusion-tight Layer on the side facing away from the space between the panes when installed Arranged outside of the hollow chamber.

According to a further embodiment, the profile body also has Landing piers for the system on the inside of the pane, which over bridge sections are connected to the side walls of the hollow chamber.

The invention succeeds in a surprisingly simple way Spacer profiles with a poorly heat-conducting material Profile body, which can have different cross-sections and with a diffusion-tight layer of good heat-conducting material is connected, the Reduce heat transfer from one disc to another and at the same time maintain good diffusion tightness.

In the following, the invention will be further explained with reference to drawings. It shows:  

Figure 1 shows a first embodiment of the spacer profile according to the invention in cross section.

Figure 2 shows a second embodiment of the spacer profile according to the invention in cross section.

Fig. 3 shows a third embodiment of the spacer profile according to the invention in cross section;

Fig. 4 shows a fourth embodiment of the spacer profile according to the invention in cross section;

FIGS. 5a and 5b exterior views of a spacer profile, partially cut away, with a line pattern or a hole pattern as an interruption;

Fig. 6 is a detailed cross-sectional view of the outer wall of a spacer profile according to the invention;

Fig. 7 shows an installation variant for a spacer profile according to the invention in an insulating window, and

Fig. 8 bar graphs of the temperatures on the inner pane surface of an insulating pane unit for different embodiments of spacer profiles according to the invention.

Figs. 1 to 4 show cross-sectional views of the inventive spacer profiles. Apart from tolerances caused by manufacturing technology, the cross section does not normally change over the entire length of the spacer profile. The drawings are only shown schematically, in particular the proportions of the diffusion-tight layer in comparison to the spacer profile are not to scale.

In Fig. 1 a first embodiment of a spacer profile is shown in accordance with the present invention. The profile body, for example made of black-colored polypropylene Novolen 1040 K, comprises an inner wall 12 , which in the installed state faces the space between the panes, two contact walls 20 and 22 intended for bearing against the inside of the pane, and a rear wall 18 adjoining them over short transition areas. A desiccant chamber 10 is defined by the approximately 12 mm thick walls 12 , 18 , 20 , 22 , which is later filled with hygroscopic material. So that moisture can enter the desiccant chamber 10 from the space between the panes, passage openings 50 are provided in the inner wall 12 . The abutment walls 20 and 22 are each provided with an indentation 90 in their surface intended for abutment on the inside of the pane, which begins at a certain distance from the ends of the abutment walls 20 , 22 facing the pane space and extends over their entire remaining area. The profile form described is the subject of the unpublished German utility model application 298 07 418.4, the content of which is referred to to avoid repetition. In the indentations 90 as well as on the outside of the rear wall 18 and the transition areas between the contact walls 20 , 22 and the rear wall 18 there is a diffusion-proof metal layer 40 made of 0.125 mm thick chromed iron plate provided with an adhesive layer, which is integrally connected to the profile body. Such a diffusion-proof layer is the subject of the unpublished German utility model application 298 07 413.3, to which reference is also expressly made. The depth of the indentation 90 corresponds exactly to the thickness of the diffusion-proof metal layer 40 , so that the contact surface formed by the profile body and the contact surface formed by the diffusion-proof metal layer 40 lie exactly in one plane.

The diffusion-tight metal layer 40 has a notch 42 on the outside, approximately 0.5 mm wide, approximately in the region of the longitudinal center plane of the spacer profile, by means of which a linear region with reduced heat conduction is formed.

The embodiment of a spacer profile according to the invention shown in FIG. 2 is based on a profile body according to German patent application 198 05 265.0. A desiccant chamber 10 is defined by walls 12, 14, 16, 18, wherein the connection between this chamber 10 and the space between the panes, or the like is prepared via passage openings 50th Via bridge sections 32 and 34 certain contact webs 30 and 36 are connected to the chamber 10 to bear against the disk inner side, wherein the contact webs 30, 36 respectively, as show in their in the installed state the disc inner sides facing surfaces in Fig. 1, an indentation 90 into which an diffusion-proof layer 40 is inserted from a 0.13 mm thick tin foil. The diffusion-tight layer 40 extends essentially from the contact surface of the first contact web 30 around it to the bridge section 32 , then around the chamber 10 to the bridge section 34 and around the contact web 36 up to its contact surface. The diffusion-tight layer 40 is completely interrupted in its thickness direction approximately in the region of the longitudinal center plane of the spacer profile. The width of the interruption 42 is in the range from 0.1 mm to 1 mm. In order to increase the diffusion tightness, the interruption 42 is covered with a bead 80 of approximately 3 mm in diameter made of a diffusion tight material which is only slightly thermally conductive. Such a material can be, for example, an isobutylene-based butyl sealant, which is usually also used for gluing the contact webs to the inner pane of the insulating pane.

The embodiment of the spacer profile according to the invention according to FIG. 3 differs from that according to FIG. 2 only in that, in addition to the first interruption 42 arranged in the longitudinal center plane of the diffusion-tight layer 40 , two further interruptions 44 and 46 running parallel thereto are provided, which are based on both sides of the first interruption 42 also extend in a line. It has been found that the thermal insulation of a spacer profile can be further improved if, instead of an interruption of a predetermined width, several interruptions 42 , 44 , 46 are provided in the diffusion-proof layer 40 , the overall width of which corresponds approximately to the width of the simple interruption. In this example, the three interruptions 42 , 44 , 46 are each designed with widths of 0.1 mm. In particular, reference is made to the exemplary embodiments in connection with FIG. 8.

Another embodiment of a spacer profile according to the invention is shown in FIG. 4. The diffusion-proof layer 40 extends here, starting from the contact sides of the contact webs 30 , 36 , essentially only up to the corner regions of the chamber 10 on the outer wall 18 of the spacer profile, the region with reduced heat conduction by reducing the thickness of the diffusion-proof layer 40 is essentially formed over the entire outer wall 18 of the chamber 10 . The thickness of the diffusion-tight layer 40 in the area of the outer wall 18 of the chamber 10 is reduced to such an extent compared to the thickness of the diffusion-tight layer in the area of the contact webs 30 , 36 that there is just sufficient diffusion-tightness of the spacer profile in this area, or it is Corresponding strip-shaped insert 48 is provided. The diffusion-tight layer 40 in the area of the contact webs 30 , 36 of the spacer profile, on the other hand, has a significantly higher layer thickness, with which a bending behavior in the sense of 198 05 265.0 can be achieved.

FIG. 5a shows partially cut away a view of a spacer profile according to the invention in the installed state from outside, is a plan view of the diffusion-proof layer 40 with the executed as an interruption 60 area of reduced thermal conduction. The interruption 60 is formed here as a slot pattern, prevents the diffusion-tight layer 40 from tearing when the spacer profile is bent or peeling off from the poorly heat-conducting material of the profile body.

Fig. 5b shows as an alternative to the embodiment of FIG. 5a is a configured as a perforated pattern 62 area of reduced thermal conduction.

Fig. 6 shows the detailed view of an embodiment of the invention, in which the region of reduced thermal conduction by the diffusion-proof layer 40 is formed only partially penetrating line-shaped recess in the form of a notch 70th Due to the local reduction in thickness in the area of the notch 70 , the heat transfer of the diffusion-tight layer 40 transverse to the longitudinal axis of the spacer profile is significantly reduced compared to a diffusion-tight layer 40 with a constant thickness, while the diffusion-tightness remains almost unchanged.

Finally, FIG. 7 shows a spacer profile according to the invention, similar to that shown in FIG. 2, installed in an insulating pane unit with the individual panes 102 , 104 , and specifically via butyl sealant based on polyisobutylene as an adhesive 106 (width between glass panes 102 , 104 and adjacent contact web 30 , 36 : 0.25 mm, height: 4 mm), and with an outside covering with polysulfide adhesive 108 at a height of 3 mm.

In Fig. 8, the temperatures determined with the aid of heat flow simulation calculations are shown -10 mm from the edge of the pane - on the surface of a room-side pane of insulating glass units ( 1 ) to ( 6 ) facing away from the space between the panes of glass, which have different spacer profile types and different designs areas have been equipped with reduced heat conduction.

The heat flow simulation calculations were carried out using the commercially available software program "WINISO 1.3" from Sommer Informatik GmbH, Rosenheim. Two-dimensional temperature fields were calculated. The glass surface temperatures shown in FIG. 8 in the region of the edge bond were determined from the representation of the calculated isotherms.

For the calculations, in addition to values for which manufacturer information was available, the thermal conductivity information according to DIN 4108 Part 4 or according to prEN 30 077 was adopted. The data are summarized in the table below.

For the calculations of the heat transport in the area of the edge bond, an insulating pane unit with individual panes made of 4 mm thick soda lime silicate float glass panes was assumed, the surface of the inner pane facing the glass pane space being provided with a heat protection layer with an emissivity of 0.1. The width of the space between the glass panes was 16 mm; for the connection of the spacers to the glass panes, butyl sealant bonds and for the outside covering a polysulfide adhesive arrangement according to FIG. 7 were assumed; a gas filling of <90% by volume with argon was assumed for the space between the glass panes.

The calculations were made with the dimensions and geometries according to the individual case play (1) - (6) performed, the outside temperature -15 ° C and the In internal temperature was 20 ° C.

In detail, the bars or pairs of bars are shown in Figure 8 correspond to the following spacer profile embodiments.:

• 1. Spacer profile according to FIG. 1 with a profile body made of polypropylene novolen 1040 K, height 6.5 mm, width 15.5 mm, wall thicknesses evenly 1 mm, with a tin-plated iron foil (tin foil) with a thickness of 0.18 mm as a diffusion-proof layer. Chemical composition of this iron sheet (in percentages by weight): carbon 0.07%, manganese 0.400%, silicon 0.018%, aluminum 0.045%, phosphorus 0.020%, nitrogen 0.007%, the rest iron. Tin layer on both sides with a basis weight of 2.8 g / m ² , which corresponds to a thickness of about 0.38 µm.
• 2. Spacer profile according to FIG. 2 with a profile body made of black colored polypropylene novolen 1040 K, height 6.5 mm, width 15.5 mm, wall thicknesses evenly 1 mm. The profile body is firmly bonded to a tin-plated sheet iron (tinplate) 0.18 mm thick as (1) as a diffusion-proof layer.
• 3. Spacer profile according to (2) with stainless steel foil 0.1 mm thick instead of Tin foil. Chemical composition of the used for the metal foil Stainless steel (in percent by weight): chrome 19 to 21%, carbon maximum 0.03%, Manganese maximum 0.50%, silicon maximum 0.60%, aluminum 4.7 to 5.5%, rest  Iron.
• 4. Spacer profile according to (2) with aluminum foil 0.1 mm thick instead of Tin foil.
• 5. Spacer profile from a U-shaped open to the space between the panes Profile body made of polypropylene, height 6.5 mm, width 15.5 mm, wall thicknesses evenly 1 mm, with a tin foil 0.18 mm thick according to (1) as diffusion-proof layer on the outside of the web and encompassing the profile legs cohesively connected.
• 6. Spacer profile according to (1) with a tin foil, but not on the the side of the profile facing away from the glass pane, but instead was continuously embedded there.

In Fig. 8, the respective bars indicate the temperatures determined on the inner pane on the surface facing away from the space between the glass panes - 10 mm from the outer edge of the pane - that is, when the spacer profiles are assumed to be covered with a 3 mm polysulfide adhesive arrangement and the spacer profile height of 6 is used , 5 mm, that the measuring point was just above the spacer profile in the direction of the space between the glass panes. The light-colored bars indicate the temperature when using the spacer profiles with a metal foil, which has a continuous, linear interruption of 0.3 mm in width in the middle in the profile longitudinal plane as an area with reduced heat conduction, while the hatched bars indicate the temperature when using a metal foil with three parallel, also continuous, line-shaped interruptions with a width of 0.1 mm, the two outer interruptions being spaced 3 mm apart from the central interruption arranged in the longitudinal plane of the profile. As a reference, the double hatched bars indicate the temperature for a spacer profile with a diffusion-tight layer without an area according to the invention with reduced heat conduction.

It is clear from the graphic representation of FIG. 8 that the thermal insulation for each of the spacer profiles examined is improved by the arrangement according to the invention of areas with reduced heat conduction in the diffusion-tight layer. It is advantageous if there are not only one, but several interruptions of small width. It has been shown that the thermal insulation is no longer significantly improved if more than three interruptions are provided. The improved thermal insulation is particularly evident in the embodiment according to (4) with aluminum as a particularly good heat-conducting material for the diffusion-tight layer.

The in the above description, in the drawings as well as in the claims Disclosed features of the invention can be used individually as well as in any Combination may be essential for the implementation of the invention.

Claims (21)

1.Spacer profile for a spacer frame of an insulating pane unit, which is to be attached in the edge region of at least two spaced-apart panes ( 102 , 104 ) to form a space between the panes, the profile body of the spacer profile consisting of poorly heat-conducting material and with essentially its entire width extending diffusion-tight layer of good heat-conducting material, characterized in that the diffusion-tight layer ( 40 ) at least one region ( 42 , 44 , 46 , 48 , 60 , 62 , 70 ) extending in the longitudinal direction of the spacer profile with reduced heat conduction transversely to the longitudinal direction of the spacer profile. 2. Spacer profile according to claim 1, characterized in that the area with reduced heat conduction is a linear recess ( 70 ) which partially penetrates the diffusion-proof layer ( 40 ) in its thickness direction. 3. Spacer profile according to claim 1, characterized in that the area with reduced heat conduction is a linear recess ( 42 , 44 , 46 , 60 ) which completely interrupts the diffusion-proof layer ( 40 ) in its thickness direction. 4. Spacer profile according to claim 2 or 3, characterized in that at least two parallel, spaced-apart linear recesses ( 42 , 44 , 46 ) are provided. 5. Spacer profile according to one of claims 2 to 4, characterized in that the linear recess ( 42 , 44 , 46 , 70 ) is designed as a continuous line. 6. Spacer profile according to one of claims 2 to 4, characterized in that the linear recess ( 60 ) is designed as a perforation. 7. Spacer profile according to one of claims 2 to 6, characterized in that the linear recess ( 42 , 44 , 46 , 70 ) has a width of at least 0.1 mm. 8. Spacer profile according to one of claims 2 to 7, characterized in that the linear recess ( 42 , 44 , 46 , 70 ) has a width of at most 1 mm. 9. Spacer profile according to one of claims 2 to 8, characterized in that the linear recess ( 42 , 44 , 46 , 60 ) is filled with a bead ( 80 ) made of a diffusion-tight, poorly heat-conducting material. 10. Spacer profile according to claim 9, characterized in that the bead ( 80 ) consists of a butyl sealant based on isobutylene. 11. Spacer profile according to claim 1, characterized in that the area with reduced heat conduction is formed by a strip-shaped insert ( 48 ) made of a poorly heat-conducting, diffusion-proof material in the diffusion-proof layer ( 40 ). 12. Spacer profile according to claim 1, characterized in that the area with reduced heat conduction is formed by a physical or chemical modification of the diffusion-tight layer ( 40 ) along a strip-shaped area. 13. Spacer profile according to one of the preceding claims, characterized in that the diffusion-tight layer ( 40 ) is arranged on the outside ( 18 ) of the profile body or is at least partially embedded in the profile body near it. 14. Spacer profile according to one of the preceding claims, characterized in that the diffusion-tight layer ( 40 ) consists of a material, in particular a metal, with a thermal conductivity λ ≦ 50 W / (mK). 15. Spacer profile according to claim 14, characterized in that the diffusion-proof layer ( 40 ) consists of stainless steel or tinned or chromed iron sheet. 16. Spacer profile according to claim 15, characterized in that the diffusion-tight layer ( 40 ) has a thickness of at least 0.02 mm. 17. Spacer profile according to claim 15 or 16, characterized in that the diffusion-proof layer ( 40 ) made of sheet iron has a thickness of less than 0.2 mm, preferably at most 0.13 mm. 18. Spacer profile according to claim 15 or 16, characterized in that the diffusion-tight layer ( 40 ) made of stainless steel has a thickness of less than 0.1 mm, preferably at most 0.05 mm. 19. Spacer profile according to one of the preceding claims, characterized records that the profile body made of a thermoplastic with a Thermal conductivity λ <0.3 W / (m.K), such as polypropylene, polyethylene terephthalate, Polyamide or polycarbonate. 20. Spacer profile according to one of the preceding claims, characterized in that the profile body has a hollow chamber ( 10 ) for receiving desiccant and that the area of reduced heat conduction ( 42 , 44 , 46 , 48 , 60 , 62 , 70 ) on the outside the hollow chamber ( 10 ) is arranged. 21. Spacer profile according to claim 20, characterized in that the profile body has contact webs ( 30 , 36 ) for abutment on the inside of the pane, which are connected to the side walls ( 14 , 16 ) of the hollow chamber via bridge sections ( 32 , 34 ).