Abstract:
A spacing profile for a spacing frame, which is to be fitted in the edge area of a double-glazing unit, forming an interspace, with a profile body of a material possessing low thermal conductivity. The spacing profile additionally comprises a desiccant cavity, and further a metal foil, which extends essentially over the entire width of the spacing profile. Only the metal foil together with a center piece of the connecting flanges forms the walls of the desiccant cavity.

Description:
BACKGROUND OF THE INVENTION 
     1. Field of the Invention 
     The invention concerns a spacing profile for a spacing frame, which is to be fitted in the edge area of a double-glazing unit, forming an interspace, with a profile body of a plastic material possessing low thermal conductivity and with a diffusion-impermeable metal foil which is bonded to the profile body so as to establish a material fit. 
     In particular, the invention relates to spacing profiles of the aforementioned type where the profile body incorporates contact flanges for contact with the insides of the panes of the double-glazing unit and a connecting flange bridging the interspace in installed state, by means of which at least two contact flanges are connected to one another, where the spacing profile additionally comprises a desiccant cavity arranged between the contact flanges and a metal foil which extends essentially over the entire width of the spacing profile, where the metal foil is bonded to establish a material fit to cavity-side surfaces of the contact flanges, as well as to adjacent end sections connecting flange. 
     The profile body made of plastic material which possesses low thermal conductivity represents the principle part of the spacing profile in respect of volume and imparts its cross-sectional profile to it. 
     Within the scope of the invention, the panes of the double-glazing unit are normally glass panes of inorganic or organic glass, without the invention being restricted thereto. The panes can be coated or otherwise finished in order to impart special functions to the double-glazing unit, such as increased thermal insulation or sound insulation. 
     2. Description of the Prior Art 
     For a considerable time, instead of metal spacing profiles, plastic spacing profiles have been used in order to take advantage of the low thermal conduction of these materials. By materials with low thermal conductivity are generally meant those which possess a coefficient of thermal conductivity which is significantly lower than that of metals, that is to say at least by a factor of 10. The coefficients of thermal conductivity X are typically of the order of 5 W/(m*K) and less; preferably, they are lower than 1 W/(m*K) and more preferably lower than 0.3 W/(m*K). 
     Of course, plastics generally possess low impermeability to diffusion in comparison with metals. In the case of plastic spacing profiles, it is therefore necessary to ensure by special means that atmospheric humidity present in the environment does not penetrate into the interspace to the extent that the absorption capacity of the desiccant generally accommodated in the spacing profiles is not soon exhausted, thus impairing the reliability performance of the double-glazing unit. Furthermore, a spacing profile must also prevent filler gases from the interspace, such as for example argon, krypton, xenon, sulphur hexafluoride, escaping from it. Conversely, nitrogen, oxygen etc., present in the ambient air may not enter the interspace. Where impermeability to diffusion is involved below, this means impermeability to vapor diffusion, as well as impermeability to gas diffusion for the gases stated. 
     To improve the impermeability to vapor diffusion, DE 33 02 659 A1 suggests to provide a plastic spacing profile with a vapor barrier by fitting a thin metal foil or a metallized plastic film on the plastic profile on the surface which faces away from the interspace in the installed state. This metal foil must fully span the interspace so that the desired vapor barrier effect occurs. 
     Nowadays, it is preferred to produce one-piece spacing frames from spacing profiles which are bent at three or four corners and for which joining of the end sections is effective by means of corner connectors inserted in the end sections or a straight connector. Here, an endeavor is made to carry out the corner bending as simply as possible in production, in particular without expensive prior heating. 
     In order to permit cold-bending of spacing profiles made of materials with low thermal conductivity, spacing profiles have been developed, where the profile body of material with low thermal conductivity and being elastically-plastically deformable is bonded to a plastically deformable reinforcing layer, preferably a metal layer, so as to establish a material fit. This reinforcing layer can also be impermeable to diffusion and span the entire width of the interspace, as a result of which the necessary impermeability to diffusion of the spacing profile is achieved. Such a spacing profile has been introduced under the name THERMOPLUS® TIS for example in the brochure “Impulse für die Zukunft (Impulses for the Future)” of Flachglas AG, Germany, and is described in the utility model DE 298 14 768 U1, which has an earlier priority date than the present patent application. In a preferred embodiment of this spacing profile, a polypropylene homopolymer having a Young&#39;s modulus of elasticity (modulus of elasticity) of 1,900 N/mm 2  is used, whereas the reinforcing layer is fabricated from sheet iron having a thickness of less than 0.2 mm or from stainless steel having a thickness of less than 0.1 mm. 
     Spacing profiles consisting of a plastics-metal-foil sandwich generally have proved in practice. Though, there is still the problem that the cold-bendability, in particular in the area of the desiccant cavity, is limited. As the desiccant cavity is relatively rigid by virtue of its closed structure reinforced on three sides, this area can only be cold-bent with difficulty. Thus, it is of course thoroughly desirable for the contact flanges, that they should, on account of the sandwich construction of elastically-plastically deformable profile body material and plastically deformable (metal) reinforcing layer, possess a high degree of rigidity, so that the contact flanges should present a flat contact surface, even after cold-bending. In the case of the desiccant cavity, a high level of rigidity has however been found disadvantageous. Above all, the side walls of the desiccant cavity impart to the profile, in accordance with the state of the art, a comparably high moment of resistance to bending so that, during the cold-bending process, uncontrolled bulging of the side walls towards the contact flanges or undesirable deformation of the connecting flange can occur. 
     In single cases, it had also been observed that in particular at high bending speeds high level deformation forces occurred at some regions, so that the material fit between profile body and metal foil could not be maintained, whereupon the metal foil peeled off the profile body at some regions and showed cracking there. In particular, the free ends of the contact flanges of a profile according to DE 298 14 768 U1 are at risk, where the metal foil experiences a high deformation stress even during manufacture of the spacing profile. The uncontrolled foil separation and tears lead to impairment of the vapor-barrier effect and to mechanical instability of the profiles. 
     SUMMARY OF THE INVENTION 
     The object of the present invention is to provide a cost-effectively producible spacing profile which, to achieve satisfactory thermal insulation, incorporates a profile body of material with low thermal conductivity which is provided with a metal foil to ensure sufficient diffusion-impermeability and where the cold-bendability as compared with the previously known profile is further improved, where undesirable deformation of the profile body, in particular of the connecting flange, and tears in the metal foils as well as undesirable foil separations can be more effectively prevented during the cold-bending process, even in profile areas which are highly stressed. 
     According to a first aspect of the invention it is provided that solely the metal foil itself together with a center piece of the connecting flange of material with low thermal conductivity should form the walls of the desiccant cavity. Thus apart from one wall, with this embodiment all the walls of the desiccant cavity are formed only of plastically deformable thin metal foil, not reinforced with a plastic layer or the like. By this means, it is possible surprisingly to achieve satisfactory cold-bendability of the profile, although tho desiccant cavity of the profile according to the invention possesses a comparatively low moment of resistance to bending. Hitherto, one was in fact convinced that a high moment of resistance to bending basically improves the cold-bendability. The walls of the desiccant cavity formed of metal foil deform more easily than the profile according to the state of the art from DE 298 14 768 U1 and over a longer profile section, so that the risk of cracking of the metal foil during bending is significantly reduced. Of course, the thickness of the metal foil may not be excessive, so that the desired satisfactory deformability of the walls of the desiccant cavity formed by the metal foil is achieved. In practice, the foil thickness will be chosen as low as possible, so that adequate impermeability to diffusion is maintained, the walls of the cavity still withstand bending free from cracks and the thermal conduction through the profile is as low as possible. 
     The inventive configuration of the spacing profile has accordingly proved successful in so to speak structurally separating the area especially critical for the cold-bendability next to the contact flanges of the desiccant cavity integrated in the profile body according to the previously known teaching, so that during the bending process no excessive deformation forces can act on the connecting flange of material with low thermal conductivity or on the contact flanges. 
     In a second aspect of the spacing profile according to the invention as well, all the walls of the desiccant cavity, apart from the inner wall formed by a center section of the connecting flange, are formed by the metal foil, where however at variance from the first embodiment, one or more of these walls are provided with a thin reinforcing layer of material with low thermal conductivity, whose thickness is however a maximum of 50% of the thickness of the connecting flange. In preference, an elastically-plastically deformable material, in particular a plastic material is used. By means of this design, it is possible, if necessary, to achieve selective local reinforcement of the desiccant cavity walls, without however the reinforcing layer assuming the structural function of the metal foil in this area of the profile and without the thermally insulating properties of the profile being significantly impaired. The reinforcing layer of the cavity walls is to be of an insignificant dimension, such that the metal foil still remains sufficiently readily deformable and that undesirably high deformation forces acting on the connecting flange when bending the profile are prevented. Here, it is possible, for example, by the use of a thin reinforcing layer to ensure that the desiccant cavity is not deformed when handling the profile or that deformation of the cavity walls during cold bending is specifically controlled. Also with this embodiment of the invention, on account of the insignificant thickness of the reinforcing layer in the area of one or more of the cavity walls formed by the metal foil, as compared with the connecting flange, the structural separation of the profile body from the desiccant cavity mentioned in connection with the first embodiment is to a large extent maintained. 
     Preferably, in both aspects, the desiccant cavity of the profile according to the invention comprises two side walls which are arranged essentially parallel to the adjacent contact flanges, as well as at least one outer wall facing away from the interspace in the installed state, which outer wall is essentially parallel to the connecting flange. In this case, the contact flanges joined to the metal foil, the end sections of the connecting flange joined to the metal foil, as well as the adjacent side walls of the desiccant cavity formed by the metal foil each form a U shape open to the outer edge of the double-glazing unit in installed state. This achieves an especially favorable cold-bendability of the spacing profile; in addition, by virtue of the U shape of the metal foil, the path formed by it of relatively high thermal conduction from one pane inside to the other pane inside is significantly extended, which contributes to improved thermal insulation of the spacing profile. Preferably, the length of the U limb of the metal foil is significantly greater than the length of the U base of the metal foil, and in particular even more than five times as great. This also ensures that the path of thermal conduction through the most efficiently thermally conductive material, that is to say the metal foil, is maintained as long as possible. Of course, the contact flanges and the adjacent side walls of the desiccant cavity can be of different lengths. In this case, the aforementioned dimensioning of the longer of the two U limbs will apply. 
     Generally, “side walls” will in each case mean the walls of the desiccant cavity nearest to the panes in installed state, irrespective of whether they are parallel to the panes in installed state or not. 
     In a preferred embodiment of the second variant, the side walls of the desiccant cavity are provided with a thin reinforcing layer of material with low thermal conductivity. By this means, it is possible to prevent undesirable bulges in the side walls during cold bending, without however undesirably high deformation forces acting on the connecting flange. The thickness of the reinforcing layer of the side walls is preferably less than one third, more preferably less than one quarter of the thickness of the connecting flange. 
     Supplementary or alternatively thereto, the outer wall of the desiccant cavity facing away from the interspace in installed state is provided with a reinforcing layer of material with low thermal conductivity. By this measure, it is possible to achieve increased stability of the profile during handling, without the thickness of the metal foil, and thus the thermal conduction, having to be increased for this purpose. Again, the thickness of the reinforcing layer of the outer wall is preferably less than one third, more preferably less than one quarter of the thickness of the connecting flange. 
     In the case of an especially preferred embodiment, at least a portion of the reinforcing layer is arranged on the inside of the walls of the desiccant cavity formed by the metal foil facing towards the interior of the cavity. This simplifies the manufacturing process for the profile, especially when the reinforcing layer is manufactured from the same material as the connecting flange. 
     In a further embodiment, the reinforcing layer covers the metal foil at least partially on both surfaces, so that the metal foil is, so to speak, embedded in these areas in the reinforcing layer, where it is to be ensured that the total thickness of the reinforcing layer, even in these areas, is not more than 50% of the thickness of the connecting flange, so as not to increase the rigidity of the cavity walls excessively. By embedding the metal foil in the reinforcing layer of (plastic) material with low thermal conductivity, the former can be protected in especially endangered areas from mechanical or chemical impairment. In addition, it is possible by this means to specifically influence the visual appearance of the spacing profile. 
     The spacing profile according to the invention is preferably manufactured by deforming the metal foil according to the desired cross-section while forming the walls of the desiccant cavity. Subsequently, a thermoplastic material which forms the profile body, i.e. the connecting flange, the contact flanges and—optionally—the reinforcing layer, is applied to the preformed metal foil by extrusion, so that a material fit of the both components is established. 
     The desired cold-bending behavior can be achieved, surprisingly, also by a specific setting of the rigidity of the plastic material of the profile body. 
     According to a third aspect of the invention, provision is thus made for a plastic material with a bending modulus of elasticity (according to DIN 53 457) of less than 1,900 N/mm 2 , in particular less than 1,500 N/mm 2 , to be used for at least the parts of the profile adjoining the metal foil. In this way it is possible to achieve the effect that the metal foil, at least in the areas especially prone to tearing, is contiguous to a relatively soft and readily deformable material, so that local peak stresses are prevented during cold-bending. According to this aspect of the invention, in particular spacing profiles having desiccant cavities and contact flanges joined thereto through bridge sections, and in particular the spacing profiles of the first both aspects of the invention can be improved regarding the cold-bending characteristics. 
     Preferably, the complete profile body will be produced entirely of a plastic material with a bending modulus of elasticity adjusted according to the invention, which will simplify manufacture and reduce the manufacturing costs. It lies within the scope of the invention, however, to manufacture parts of the profile, such as for example the profile inner wall contiguous to the interspace, of a more rigid material, in order to impart increased rigidity to the profile. This can for example take place by using another plastic material of higher bending modulus of elasticity or by addition in some areas of customary reinforcing agents to the plastic material used according to the invention, where these reinforcing agents are preferably glass fibers. Here, it is possible to resort to materials known from the state of the art. From EP 0 745 470 A1, for example, a homogeneous profile bar is also known which can be used as spacing profile for double-glazing units, which consists of a polyolefine with embedded glass fibers. Here, modulus of elasticity values of 5,500 N/mm 2  and above are reached. In addition, a spacing profile for double-glazing units is known from EP 0 127 739 B1 which consists of a polypropylene filled with glass fibers or mineral powder. 
     Another alternative consists of using a plastic material adjusted according to the invention only for the parts of the profile body especially at risk, in particular for walls or contact flanges bonded to the metal foil, arranged approximately parallel to the pane plane in installed state, and to produce the remainder of the profile body subjected to less mechanical strain during cold-bending of a material with a higher bending modulus of elasticity. 
     The plastic material will preferably possess a tensile strength at yield (according to DIN EN ISO 527-1) of less than 38 N/mm 2 , preferably a maximum of 30 N/mm 2 , and an elongation at yield (according to DIN EN ISO 527-1) of over 7%, preferably at least 8%. 
     On account of the low bending modulus of elasticity of the plastic material used for the profile body or parts thereof and of the associated low tensile strength at yield or high elongation at yield of this material, the spacing profile is overall more readily deformable with avoidance of local peak stresses, so that the risk of separation or even tearing of the metal foil during cold-bending is significantly reduced. On the other hand, the rigidity of the spacing profile can be maintained at such a high level by bonding the metal foil to the profile body so as to form a material fit in case of using a suitable profile geometry that undesirable deformation of the spacing profile can be prevented during cold-bending, especially in the region of contact flanges. 
     Especially when the profile body consists entirely of a plastic material with low bending modulus of elasticity according to the invention, the bending modulus of elasticity should not be less than a value of 900 N/mm 2 , so that the rigidity of the profile as a whole is still sufficiently high. 
     Further, improved cold-bending properties are achieved with a plastic material whose percentage elongation at break (according to DIN EN ISO 527-1) is at least 100%, preferably 500%. The effect of this is that, even in the region of plastic deformation following the elastic deformation of the plastic material, no tear can occur in the plastic profile body which would lead to local excessive mechanical loading of the metal foil during bending. 
     With the optimized mechanical material properties of the plastic material used for the profile body, the inventive sandwich of profile body and metal foil possesses the necessary mechanical properties (cold-bendability) for problem-free manufacture of one-piece spacing frames, as well as the high level of impermeability to diffusion and low level of thermal conductivity required for use in double-glazing units. 
     Basically, several plastic materials can be used for implementation of the invention. Preferably of course, the plastic materials used include polypropylene as principal constituent. Especially preferred are polypropylene block copolymers, especially those with grafted polypropylene or polyethylene. This material group possesses an especially favorable range of properties in connection with the purpose of the invention. 
     The material for the profile body which is preferred according to the invention, is generally suitable to manufacture a profile which profile body comprises a hollow profile of rectangular cross-section which encloses a cavity to accommodate desiccant. Of course, the cavity must incorporate perforations or the like in the inner wall facing towards the interspace in order to establish a gas-conducting connection with the interspace. This aspect of the invention is, however, to be used to special advantage in the case of spacing profiles according to DE 298 14 768 U1. In this case, the profile body incorporates contact flanges for contact with the inside of a pane which are joined via bridge sections to a desiccant cavity. The metal foil is bonded to the contact surface of the contact flanges, to the surfaces of the bridge sections facing away from the interspace and to the outer surfaces of the walls of the desiccant cavity so as to establish a material fit. 
     In a preferred embodiment of the invention it is provided that the metal foil is arranged at least on a portion of the contact surfaces of the contact flanges facing to the insides of the panes in the installed state. By this means, an increased stability of the contact flanges during cold-bending as well as a good adhesion to the sealing material is achieved. 
     The occurrence of tears during cold-bending can be prevented especially sufficiently if the metal of the metal foil is selected so that its elongation at break (according to ISO) is more than 15%. 
     The thickness of the metal foil is preferably between 0.02 mm and 0.3 mm, especially preferably between 0.1 mm and 0.15 mm, while the thickness of the connecting flange is preferably between 0.5 mm and 1.5 mm. This dimensioning of the principal components of the spacing profile according to the invention has proved satisfactory in imparting favorable cold-bendability when using known materials and being able to produce the profile cost-effectively. 
     Suitable materials for the metal foil are in particular stainless steal or chromium-plated or tin-plated sheet iron, where the thickness of the metal foil should be at most 0.2 mm and at least 0.05 mm, in case of sheet iron at least 0.1 mm. 
     Preferred values for the thickness of the metal foil are approximately 0.08-0.1 mm in the case of stainless steal and approximately 0.1-0.13 mm in the case of sheet iron. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     The invention will be explained below with the aid of the embodiments illustrated in the figures. These show: 
     FIG. 1 a first embodiment of a spacing profile according to the invention; 
     FIG. 2 a second embodiment of the spacing profile according to the invention; 
     FIG. 3 a third embodiment of the spacing profile according to the invention; 
     FIG. 4 a fourth embodiment of the spacing profile according to the invention, and 
     FIG. 5 a fifth embodiment of the spacing profile according to the invention. 
    
    
     DESCRIPTION OF THE PREFERRED EMBODIMENT 
     FIGS. 1 to  5  show cross-sectional views of spacing profiles according to the invention. Apart from manufacturing tolerances, this cross-section does not normally change over the entire length of a spacing profile. 
     Identical or similar elements in the different embodiments have been provided with the same reference numerals. The drawings are only diagrammatical; in particular the thickness of the metal foil is not represented to scale. 
     FIG. 1 shows a first embodiment of a spacing profile according to the present invention. The profile body comprises two contact flanges  10  for contact in each case with the inside of a pane of a double-glazing unit and a connecting flange  20  which connects the contact flanges  10  with one another and in detailed state bridges the interspace. The profile body has been manufactured in the example illustrated from black-tinted polypropylene Novolen 1040 K with a thickness of 1 mm. It is however preferred to use one of the materials 1 or 2 further characterized below according to the third aspect of the invention. 
     As metal foil  40 , a chromium-plated sheet iron foil with a thickness of 0.125 mm was used. The metal foil  40  is laminated onto the free edges of the contact flanges  10  and onto the cavity-side surfaces  11  of the contact flanges  10  and onto the adjacent end sections (bridge sections)  21  of the connecting flange  20 . 
     At a center piece  22  of the connecting flange  20 , the metal foil  40  is arranged at a distance from the connecting flange  20 , whereby a cavity is formed, which can be used as desiccant cavity  30 . Here, the center piece  22  of the connecting flange  20  forms the inner wall of the desiccant cavity  30 , while the metal foil  40  forms the other three walls  32 ,  34 ,  36  of the desiccant cavity  30 , which possesses an essentially rectangular cross-section. 
     The center piece  22  of the connecting flange  20  is provided in the area of the desiccant cavity  30  with perforations  23 , so that in installed state moisture from the interior of the double-glazing unit can be absorbed by the desiccant (not shown) introduced into the desiccant cavity  30 . 
     FIG. 2 shows a second embodiment of a spacing profile according to the invention in cross-section. Here, the profile body, in the example again manufactured from polypropylene Novolen 1040 K, consists of contact flanges  10  and a connecting flange  20 , where from the ends of the center piece  22  of the connecting flange  20  project two thin reinforcing layers  50 , which are joined to the inner surfaces  51  of the side walls  32 ,  34  of the desiccant cavity  30  and also consist of polypropylene Novolen 1040 K. The metal foil  40  is laminated onto the edges of the contact flanges  10  as well as onto those surfaces of the contact flanges  10 , facing the cavity and the adjacent end sections  21  of the connecting flange  20 , and in addition forms the outer wall  36  as well as the side walls  32 ,  34  of the desiccant cavity  30  adjacent thereto at a right angle. The reinforcing layers  50  stabilizing the side walls  32 ,  34  possess a thickness of approximately 0.25 mm, which corresponds to approximately one quarter of the thickness of the profile body, that is to say the thickness of the connecting flange  20  and the contact flanges  10 . 
     As metal foil  40  was used for the example a tinned sheet iron foil (tinplate foil) with a thickness of 0.125 mm. 
     The chemical composition of this sheet iron was (in weight percent): Carbon 0.07%, manganese 0.400%, silicon 0.018%, aluminium 0.045%, phosphorus 0.020%, nitrogen 0.007%, remainder iron. 
     To the sheet was applied a coating of tin with a mass per unit area of 2.8 g/m 2 , which corresponds to a thickness of 0.38 μm. 
     FIG. 3 illustrates a further embodiment of a spacing profile according to the invention in cross-section. To the profile body, consisting of contact flanges  10  and the connecting flange  20 , is joined a desiccant cavity  30  formed by a metal foil  40  and the center piece  22  of the connecting flange  20 , whose side walls  32 ,  34  are joined to thin stabilizing reinforcing layers  50  and its outer wall is joined to a further thin stabilizing layer  60 . 
     All reinforcing layers  50 ,  60  have in the examples illustrated, like the profile body, been manufactured from polypropylene Novolen 1040 K. They possessed a thickness of 0.15 mm, which corresponded to approximately 15% of the thickness of the connecting flange  20 . As metal foil  40  a stainless steel foil with a thickness of 0.05 mm was used. It had been laminated onto the contact surface  12  of contact flanges  10  facing towards the insides of the panes in installed state, the edges of contact flanges  10 , the cavity-side surfaces  11  of the contact flanges  10  and the adjacent end sections  21  of the connecting flange  20 , and in addition formed, as mentioned, the side walls  32 ,  34  and the outer wall  36  of the desiccant cavity  30 . 
     The chemical composition of the stainless steel used for the metal foil  40  was (in weight percent): Chromium  19  to 21%, carbon maximum 0.03%, manganese maximum 0.50%, silicon maximum 0.60%, aluminium 4.7 to 5.5%, remainder iron. 
     FIG. 4 illustrates a further embodiment of a spacing profile according to the invention, which differs from the embodiment illustrated in FIG. 3 by the fact that the reinforcing coating  60  joined to the outer wall  36  of the desiccant cavity  30  formed by the metal foil  40  is arranged on the outside of the outer wall  36 , thus protecting the latter more efficiently from mechanical and chemical impairment. 
     The spacing profiles according to FIGS. 1 to  4  could be cold-bent to form a rectangular spacing frame without undesired deformations in a standard automatic bending machine customary in commerce. 
     FIG. 5 shows a fifth embodiment of the spacing profile according to the invention having a profile body according to DE 298 14 768 U1. By walls  32 ,  34 ,  36  and the center piece  22  of the connecting flange  20 , a desiccant cavity  30  is defined, wherein the gas-conducting connection between this cavity  30  and the interspace is provided by perforations  23 . End sections  21  of the connecting flange  20  form, as in the case of FIG. 1, bridge sections between the desiccant cavity  30  and contact flanges  10 , the contact flanges  10  comprising each a recess  70  in those surfaces facing to the inside of the panes in the installed state, a metal foil  40  being inserted into the recesses  70 . The depth of the recess  70  corresponds exactly to the thickness of the metal foil  40 , so that the contact surface formed by the profile body  1  and the contact surface formed by the metal foil  40  lie exactly on one plane. The represented profile shape is subject of the utility model application DE 298 07 418.4 which has an earlier priority date than the present application. In order to avoid repetitions, reference is made to the full content of the utility model application. The metal foil  40  extends substantially from the contact surface of the first contact flange  10  there around to the first end section  21 , then around the cavity  30  to the second end section  21  and around the second contact flange  10  to its contact surface. A sheet iron which is chrome-plated and provided with a metal primer layer, the sheet having a thickness of 0.125 mm, has been used as the diffusion-impermeable metal foil  40  establishing a material fit with the profile body  1 . Such a diffusion-impermeable iron sheet foil is subject of the utility model application DE 298 07 413.3 which has an earlier priority date than the present patent application and to which reference is also explicitly made. Alternatively, beside further suitable materials, also a stainless steel can be used for the metal foil  40 , in this case the thickness being preferably between 0.08 and 0.1 mm. It must be endeavored that independently of the material the elongation at break of the metal foil  40  used should be greater than 15% prior to deformation and attachment to the profile body. 
     For the profile body, instead of the material polypropylene Novolen 1040 K mentioned in the description to the previous figures, black-tinted plastic materials according to the third aspect of the invention having the following composition were used: 
     
       
         
               
               
               
             
           
               
                   
               
               
                   
                   
                 Proportion 
               
               
                 Material component 
                 Trade name 
                 in weight % 
               
               
                   
               
             
             
               
                 Material 1: 
                   
                   
               
               
                 Polypropylene block 
                 Borealis BA 101 E natur of 
                 73% 
               
               
                 copolymer with 
                 Borealis A/S, Lyngby, 
               
               
                 grafted polyethylene 
                 Denmark 
               
               
                 content 
               
               
                 Polypropylene with 20 
                 Borealis MB 200 U natur of 
                 24% 
               
               
                 weight % 
                 Borealis A/S, Lyngby, 
               
               
                 French chalk content 
                 Denmark 
               
               
                 Material 2: 
               
               
                 Polypropylene 
                 Adstif 680 ADXP natur of 
                  5% 
               
               
                 homopolymer 
                 Montell, Wesseling, Germany 
               
               
                 Polypropylene block 
                 Borealis BA 101 E natur of 
                 68% 
               
               
                 copolymer with 
                 Borealis A/S, Lyngby, 
               
               
                 grafted polyethylene 
                 Denmark 
               
               
                 content 
               
               
                 Polypropylene with 20 
                 Borealis MB 200 U natur of 
                 24% 
               
               
                 weight % 
                 Borealis A/S, Lyngby, 
               
               
                 French chalk content 
                 Denmark 
               
               
                 Reference Material: 
               
               
                 Polypropylene 
                 Adstif 680 ADXP natur of 
                 73% 
               
               
                 homopolymer 
                 Montell, Wesseling, Germany 
               
               
                 Polypropylene with 20 
                 Borealis MB 200 U natur of 
                 24% 
               
               
                 weight % 
                 Borealis A/S, Lyngby, 
               
               
                 French chalk content 
                 Denmark 
               
               
                   
               
             
          
         
       
     
     Each of the plastic materials also contained 1 weight % of a suitable color batch (black pigments), as well as 2 weight % of a UV stabilizer. The plastic materials possessed the mechanical properties shown in the following Table: 
     
       
         
               
               
               
               
             
           
               
                   
               
               
                   
                   
                   
                 Reference 
               
               
                 Measured quantity 
                 Material 1 
                 Material 2 
                 Material 
               
               
                   
               
             
             
               
                 Bending modulus of 
                 1,180 N/mm 2   
                 1,280 N/mm 2   
                 2,083 N/mm 2   
               
               
                 elasticity (DIN 53457) 
               
               
                 Elongation at yield 
                 9.4% 
                 8.8% 
                 3.9% 
               
               
                 (DIN EN 527-1) 
               
               
                 Tensile strength at yield 
                 24.8 N/mm 2   
                 26.3 N/mm 2   
                 34.8 N/mm 2   
               
               
                 (DIN EN ISO 527-1) 
               
               
                 Elongation at break 
                 &gt;800% 
                 &gt;750% 
                 4.1% 
               
               
                 (DIN EN ISO 527) 
               
               
                 Tensile strength at break 
                 21.9 N/mm 2   
                 21.3 N/mm 2   
                 15.7 N/mm 2   
               
               
                 (DIN EN ISO 527) 
               
               
                 Notched impact strength 
                 29.9 kJ/m 2   
                 22.0 kJ/m 2   
                 4.1 kJ/m 2   
               
               
                 (DIN EN ISO 179) 
               
               
                 Shore D hardness 
                 67 
                 69 
                 76 
               
               
                 (DIN 53505) 
               
               
                 Density (DIN 53479) 
                 0.94 g/cm 3   
                 0.94 g/cm 3   
                 0.95 g/cm 3   
               
               
                   
               
             
          
         
       
     
     The spacing profile according to FIG. 5 was cold-bent in a standard automatic bending machine to form a right-angled spacing frame. It deformed as desired in the area of the corners in the case of materials 1 and 2, without tears in the metal foil  40 , foil separation or other undesirable deformation occurring, especially in the areas of the contact flanges  10 . When the reference material, which possessed a significantly higher bending modulus of elasticity, and also differed significantly from the other materials in respect of tensile strength at yield, elongation at yield and elongation at break, was used for the profile body on the other hand tears were observed in the most seriously stressed areas of the metal foil  40 , so that the spacing profiles produced in this way had to be evaluated as defective. 
     The features disclosed in the foregoing description, in the claims and/or in the accompanying drawing may, both separately and in any combination thereof, be material for realizing the invention in diverse forms thereof.