DE202015010024U1 - Spacer for insulating glass panes - Google Patents

Abstract

Spacer for insulating glass panes, comprehensive
a profile body which is essentially rectangular in cross section and designed as a closed hollow profile,
wherein the profile body has a first and a second side wall arranged parallel to one another and spaced apart from one another, an inner wall extending between the first and the second side wall and an outer wall extending from the first to the second side wall and spaced from the inner wall,
wherein the outer wall has a first wall section aligned essentially parallel to the inner wall and second and third wall sections arranged on both sides of the first wall section, the latter of which are aligned at an obtuse angle to the first wall section and to the respectively adjacent side wall when viewed in cross section perpendicular to the axial direction of the profile body and to these connect,
wherein at least the inner wall, the first and second side walls and the second and third wall sections of the outer wall are manufactured using a first plastic material,
and wherein the spacer comprises a one-piece primary reinforcing element which extends from the first side wall over the outer wall to the second side wall and is designed as a vapor diffusion barrier,
characterized in that the profile body has a reduced wall thickness in the wall areas in which the second and third wall sections of the outer wall adjoin the first and second side walls to form joint points.

Description

The invention relates to a spacer for insulating glass panes, as they are used in a variety of ways in the production of windows, doors, facade elements, etc.

The spacer typically comprises a profile body with a substantially rectangular cross-section and designed as a closed hollow profile, the profile body having a first and a second side wall arranged parallel to one another and spaced apart from one another, an inner wall extending between the first and second side walls and an inner wall extending from the first to the first has an outer wall extending to the second side wall. The outer wall is spaced apart from the inner wall and has a first wall section aligned essentially parallel to the inner wall and second and third wall sections arranged on both sides of the first wall section, which are at an obtuse angle to the first wall section and the respectively adjacent ones, viewed in cross section perpendicular to the axial direction of the profile body Side wall are aligned and connect to it. At least the inner wall, the first and second side walls and the second and third wall sections of the outer wall are made of a first plastic material. The spacer further has a one-piece primary reinforcing element which extends from the first side wall over the outer wall to the second side wall and is designed as a vapor diffusion barrier.

Spacers for insulating glass panes of this type are known in the prior art, for example from US Patent 4,719,728 , the WO 2014/005950 A1 as well as from the DE 10 2010 049806 A1 .

There is often a requirement to be able to form the spacers for insulating glass panes into a frame using a cold bending process, with the outer geometry of the corner regions of the frame then formed, particularly in the area of the side walls, remaining as unchanged as possible, so that the spacers fit precisely with the side walls on the glass panes of the insulating glass panes.

Furthermore, it is important to design the profile body in such a way that the space between the panes in the insulating glass panes can be kept essentially free of water vapor and thus condensation effects can be avoided when there are large differences between the inside and outside temperatures. For this purpose, the spacers are filled, for example, in their hollow profile with a desiccant, for which, however, only a limited volume is available, so that the gas-tight, in particular moisture-tight, sealing of the space between the panes from the environment by the spacer is of crucial importance.

The spacers are also required to have a certain mechanical stability so that they can be easily processed using conventional cold bending processes.

As is known in the prior art, the spacers according to the invention are used to improve the thermal insulation of insulating glass panes of windows, doors, facade elements and the like instead of the previously common metal spacers in order to keep the two panes of glass at a distance.

The flexibility for producing the frames on the one hand, but also the longitudinal stability of the spacers on the other hand, are of great importance during processing.

The object of the present invention is to propose a spacer that can be deformed in particular in the cold bending process with conventional systems, offers the greatest possible thermal resistance and can also be manufactured economically.

This object is achieved according to the invention with the features of claim 1.

The fact that, on the one hand, the spacer according to the invention has a primary reinforcing element, which is formed in one piece and extends from the first to the second side wall, which is simultaneously designed as a vapor diffusion barrier, as is known in the prior art, in combination with which wall areas are provided , which form joint points via which the outer wall connects to the first or second side wall, on the one hand sufficient stability of the spacer and on the other hand good cold formability can be achieved.

In particular, due to the joint points present in combination with the one-piece primary reinforcing element in the transition from the side walls to the outer wall or their second and third sections, the cold bendability is improved in a controlled manner, so that the mechanical stress on the profile body during bending is reduced. This allows optimization of the wall thicknesses of the inner wall, the side walls and also the outer wall, provided the latter is made of a plastic material.

This not only leads to a further increase in the thermal resistance, but also reduces material costs and simplifies handling, especially in the cold bending process, for example by reducing the so-called overbending angle.

The second and third wall sections of the outer wall are preferably designed to be essentially planar, whereby an outer contour of the spacer is achieved which offers sufficient space for the application of a sealant when installing the spacer between the panes of the insulating glass panes.

The primary reinforcing element is preferably designed as a metal foil, in particular as a stainless steel foil. More preferably, the thickness of the metal foil is limited to approximately 0.1 mm or less, in particular to approximately 0.09 mm or less. Such thin metal foils can still fulfill their function as a primary reinforcing element, but at the same time reduce the heat transfer compared to thicker foils.

With regard to the areas of the profile body that are made of plastic material, at least in some areas the inner and outer walls can be designed to be porous, in particular closed-pore, and, for example, made of foamed plastic material. These embodiments enable a further improvement in the thermal resistance without the cold bendability being processed or the mechanical properties of the spacer being substantially impaired.

The side walls can also be designed with a porous structure, which in turn is chosen to be particularly closed-pore. If necessary, the profile body can then be produced essentially completely with a porous, in particular closed-pore, structure.

Profile bodies with a porous structure (foam structure) formed in part or in the entire cross section surprisingly have the further advantage that, due to the foam structure, the so-called overbending angle or, in other words, the recovery behavior when bending in the cold bending process is reduced.

Furthermore, profile bodies with a foam structure formed in part or over the entire cross section have the advantage that the connection of spacer ends using corner connectors or longitudinal connectors is easier and, in addition, an improved positive connection with the surface structuring provided by the corner and longitudinal connectors can be achieved due to the compressibility of the foam structure is.

In a special embodiment of the spacers according to the invention it is provided that the outer wall is partially formed by the primary reinforcing element, preferably at least the first wall section of the outer wall being formed essentially completely by the primary reinforcing element. On the one hand, this not only saves plastic material and thus costs and weight, but also results in a larger volume in the hollow profile to accommodate desiccant, with the same overall height.

If a higher volume is not required to accommodate the desiccant, the overall height of the spacer can be reduced - with the advantage that, in addition to saving material, the weight of the profile body can also be reduced. A lower overall height of the spacer also reduces the heat transfer coefficient for the edge seal of the insulating glass pane, although the reduction in the overall height of the spacer is limited by the required mechanical stability of the edge seal.

Alternatively, it can be provided that the first wall section of the outer wall is made of a second plastic material, the second plastic material of the first wall section of the outer wall preferably being compatible with the first plastic material or possibly also identical.

Further preferably, the first wall section of the outer wall, if it is made of the second plastic material, is formed in one piece with the profile body, with extrusion or coextrusion being particularly suitable here.

Furthermore, it can be advantageous to connect the first wall section with the second and third wall sections via wall areas that have a smaller wall thickness and thus form joint points. The joint points between the first and the second or third wall section of the outer wall have the additional effect of increasing the heat transfer resistance of the outer wall. This effect can also be observed, albeit to a lesser extent, in the joint points provided between the second and third wall sections of the outer wall and the respective associated side walls.

The reduced wall thickness to form the joint points can also affect neighboring walls rich, in particular the outer wall, can be expanded, so that, for example, starting from the joint points, up to approximately a third of the extent of the outer wall in the transverse direction of the spacer has a reduced wall thickness.

The wall areas designed as joint points are preferably designed as grooves formed in the interior of the hollow profile of the profile body, so that when the spacer is deformed when corner areas are formed in the course of cold forming, the lowest possible resistance occurs on the part of the plastic material in the joint areas, since the areas which would otherwise be subject to compression, are left out by the formation of the groove.

In addition, the design of the groove can influence the deformation of the spacer on its outside during cold bending to a certain extent, so that this area is specifically subjected to deformation.

Depending on the size, in particular width, of the spacer, it can be advantageous if a first and a second secondary reinforcing element are arranged in the inner wall of the spacer parallel to the axial direction of the spacer, the first primary reinforcing element being arranged in a section of the inner wall adjacent to the first side wall and the second secondary reinforcing element in a second section of the inner wall adjacent to the second side wall.

The secondary reinforcing elements are preferably arranged in the inner wall at a distance from the respective side walls which corresponds to approximately 10 to approximately 40%, more preferably approximately 30 to approximately 35%, of the distance between the side walls. This allows the profile geometry to be adapted to the tools used during the bending process.

Furthermore, the secondary reinforcing elements can preferably be arranged in the inner wall at a distance from the side wall adjacent to them of approximately 1 mm to approximately 5 mm, more preferably approximately 1 mm to approximately 3 mm.

The distance is defined as the distance between the center point (with a circular cross section) of the secondary reinforcing elements and the adjacent side wall. In the case of a cross-section that deviates from the circular shape, its geometric center of gravity should be used instead of the center point to determine the distance.

The secondary reinforcing elements can in particular be wire-shaped, with flat wires also proving to be suitable with a view to keeping the wall thickness of the inner wall as small as possible.

The reinforcing elements, in particular in wire form, also in the form of flat wires, preferably have a structuring, in particular corrugation, or other contouring on their outside transverse to their longitudinal direction, so that these reinforcing elements can be introduced into the surrounding plastic material in a shear-resistant manner and thus at the same time the function can take over to limit the thermal elongation of the profile of the spacer. Alternatively or additionally, the secondary reinforcing elements can also be equipped with an adhesion promoter layer. Furthermore, the secondary reinforcing elements can also be equipped with an adhesive layer, for example made of a so-called hot melt adhesive.

To accommodate the secondary reinforcing elements in the inner wall, this preferably has thickenings or projections which extend into the cavity of the hollow profile and which are essentially adapted to the contour of the secondary reinforcing elements. The secondary reinforcing elements can be safely embedded in these areas, which have a greater wall thickness than the adjacent areas of the inner wall. In particular, this prevents the reinforcing elements from emerging from the plastic material of the inner wall during cold bending and thereby losing physical contact with the inner wall. When cutting the spacers to length by sawing, it is also advantageous to securely embed the secondary reinforcing elements in the inner wall so that the reinforcing elements are not torn out in the cutting area.

The greater wall thickness in the area of the projections is preferably based on the thickness of the secondary reinforcing elements, according to their orientation and measured perpendicular to the surface of the inner wall.

Further preferably, the inner wall, at least in its areas in which the first and second reinforcing elements are arranged, will have a thickness that is approximately 1.5 to approximately 3.5 times, in particular approximately 1.6 times. up to approximately 2.9 times the extent of the cross section of the primary reinforcing elements in this direction.

In order to improve the cold bendability of the spacers according to the invention which have secondary reinforcing elements, and in particular those which accommodate the reinforcing elements in projections which extend into the cavity of the hollow profile, it is preferably provided that the outer wall in areas corresponding to the positions of the secondary reinforcing elements lie opposite, have a recess which preferably corresponds to approximately a quarter to approximately half, more preferably approximately a third to approximately half of the thickness of the secondary reinforcing elements and/or corresponds to the contour of the projections of the inner wall.

The plastic materials from which the first and also the second plastic material are preferably selected include polypropylene (PP), polycarbonate (PC), polyvinyl chloride (PVC), styrene-acrylonitrile copolymers (SAN), polyester, in particular polyethylene terephthalate (PET), polyamide ( PA) and acrylonitrile-butadiene-styrene copolymers (ABS) individually or in mixtures with one another.

Polycarbonate (PC), polypropylene (PP) and polyester, in particular polyethylene terephthalate (PET), can also be used partially or fully for the first and second plastic materials in the form of recyclate. This reduces material costs, while the requirements for the mechanical strength values of the spacer profiles according to the invention can still be met.

Likewise, biodegradable or bio-based polymers, for example low molecular weight polyamide (PA), polyester, polyvinyl alcohol (PVA), polybutylene adipate terephthalate (PBAT), polybutylene succinate (PBS), polycaprolactose (PCL) and polyglycolide (PGA) or starch, sucrose, polylactide (PLA), polyhydroxybutyrate (PHB), lignin-based thermoplastics and oil-based epoxy acrylates are used as the first and/or second plastic material.

These recyclates and biodegradable plastic materials are preferably used together with fillers selected from natural fibers. Preferred natural fibers are selected from coconut fibers, hemp fibers, sisal fibers, flax and wood fibers. The natural fibers do not lead to an improvement in the mechanical properties to the same extent as the thermoplastic fibers or even the glass fibers, but they also bring about an improvement in the thermal insulation properties of the plastic materials.

The weight ratio of the weight of the primary reinforcing element to the weight of the first and optionally second plastic material is preferably selected in the range from approximately 1:0.75 to approximately 1:3.

In the case of the preferred spacers according to the invention, the mechanical stability and in particular their thermal linear expansion behavior can be positively influenced by the incorporation of reinforcing fibers into the plastic material. This applies to both the first and second plastic material.

Preferably, the content of reinforcing fibers is approximately 20% by weight or less, in particular 10% by weight or less, in view of their higher thermal conductivity compared to the plastic material.

Inorganic fibers such as glass fibers, basalt fibers, carbon fibers, boron fibers, ceramic fibers and silica fibers are used in particular as reinforcing fibers. Preferred organic reinforcing fibers are aramid fibers, polyamide fibers, polyester fibers, polyolefin fibers and plexiglass fibers for use.

Metallic fibers, especially steel fibers, are also suitable as reinforcing fibers.

In an alternative embodiment of the spacers according to the invention, the first and/or the second plastic material is free of reinforcing fibers, with optimal thermal insulation values being achieved here.

Further preference is given to using additives in the first and/or second plastic materials, which are in particular selected from fillers, pigments, light stabilizers, impact modifiers, antistatic agents and/or flame retardants.

More preferred spacers may have an inner wall which has a reduced thickness in areas directly adjacent to the side walls compared to the thickness of the areas extending towards the center of the profile. These areas with reduced wall thickness also form joint points that facilitate the deformation of the spacer when forming corner areas when the spacer is cold bent into a frame and contribute to the formation of a predetermined, controlled geometry of the bent spacer.

This applies in particular when first and second secondary reinforcing elements are arranged in the inner wall.

When selecting materials for the primary reinforcing element and the secondary reinforcing elements elements, it is preferred to ensure that the material of the primary reinforcing element has a greater elongation at break than the secondary reinforcing elements, which are more likely to be exposed to compression during the cold bending process, while the primary reinforcing element, which also extends in the area of the outer wall of the spacer, is subject to elongation due to tensile forces Is subjected to cold bending.

Here it is particularly advantageous if the material of the primary reinforcing element has a low yield strength, as is present in materials that have not been further work-hardened. After annealing, such materials should only be straightened or stretch-bend-straightened without noticeably increasing the tensile strength or yield point.

Further preferred spacers are designed in such a way that the first and second secondary reinforcing elements are each arranged adjacent to a part of the hollow volume of the hollow profile, in which even after bending of the hollow profile to form a corner region about a perpendicular to the axial or longitudinal direction and parallel to the inner wall extending bending axis by 90 °, the inner wall and the outer wall are spaced apart from each other. This has the advantage that the first and second secondary reinforcing elements do not offer any resistance to the bending process in the cold bending process that goes beyond their actual material strength.

Particularly preferred are spacers in which the hollow profile has a neutral axis or fiber perpendicular to the longitudinal direction and parallel to the inner wall when bent, which lies in the range of approximately 40% to approximately 60% of the total height of the hollow profile.

Further preferred are spacers in which the profile body has an overbending angle for the production of a 90° bent section using the cold bending process, which is approximately 20° or less, more preferably approximately 15° or less.

Preferred spacers have a wall thickness of the inner wall and/or the first, second and third wall sections of the outer wall, which is approximately 0.7 mm to approximately 1 mm, preferably approximately 0.7 mm to approximately 0.9 mm.

Furthermore, the wall thickness can be in the range of approximately 0.3 mm to approximately 0.7 mm, at least in one or more areas in the profile cross section. However, the inner wall will preferably have a regular wall thickness, for example of approximately 0.9 mm, in the areas in which a perforation is provided, via which the cavity of the hollow profile communicates with the space between the panes. With the areas of reduced wall thickness, in addition to further improving the thermal insulation properties of the spacer according to the invention, additional material is saved and the weight of the spacer is reduced.

The wall thickness of the side walls is less critical, as it only plays a minor role with regard to the thermal insulation properties of the spacer.

• 1: ein erstes Ausführungsbeispiel eines erfindungsgemäßen Abstandhalters;
• 2: ein zweites Ausführungsbeispiel eines erfindungsgemäßen Abstandhalters;
• 3: ein drittes Ausführungsbeispiel eines erfindungsgemäßen Abstandhalters;
• 4: ein viertes Ausführungsbeispiel eines erfindungsgemäßen Abstandhalters;
• 5: ein fünftes Ausführungsbeispiel eines erfindungsgemäßen Abstandhalters; und
• 6: ein sechstes Ausführungsbeispiel eines erfindungsgemä-ßen Abstandhalters.

These and other advantages of the invention are explained in more detail below with reference to the drawings. They show in detail:

• 1 : a first embodiment of a spacer according to the invention;
• 2 : a second embodiment of a spacer according to the invention;
• 3 : a third embodiment of a spacer according to the invention;
• 4 : a fourth embodiment of a spacer according to the invention;
• 5 : a fifth embodiment of a spacer according to the invention; and
• 6 : a sixth embodiment of a spacer according to the invention.

1 shows a spacer 10 according to the invention according to a first exemplary embodiment with a profile body 12, which has a first and a second side wall 14, 16 arranged parallel to one another and spaced apart from one another, between which an inner wall 18 extends.

Parallel to the inner wall 18 and at a distance from it, an outer wall 20 extends from the first to the second side wall, which has a central wall section 22 arranged parallel to the inner wall 18 and second and third wall sections 24, 26 on both sides of the first wall section, which are in cross section Seen in the axial direction of the profile body (as shown here), the first wall section 22 and the adjacent side wall 14, 16 are aligned at an obtuse angle and connect to them.

The wall area of the profile body, in which the side wall 14 and the second wall section 24 of the outer wall 20 adjoin one another, is designed with a smaller wall thickness to form a joint point 28. The second side wall 16 is also connected to the third wall section 26 of the outer wall 20 via a wall area with ver reduced wall thickness to form a joint 30.

On the outer surface of the spacer 10, a one-piece primary reinforcing element 32 is provided in the area from the side wall 14 over the outer wall 20 to the side wall 16, which at the same time takes on the function of a vapor diffusion barrier.

In the case of the present exemplary embodiment of the spacer 10, the primary reinforcing element 32 is designed as a stainless steel foil with a thickness of approximately 0.09 mm, the mechanical properties of which are sufficient to reinforce the spacer 10 so that it can be cold-bent using conventional cold bending systems to form Corner areas of a spacer frame.

Optionally, the exemplary embodiment of a spacer 10 according to the invention has a first and a second secondary reinforcing element 34, 36 embedded in the inner wall 18, which are preferably designed as metal wires with a corrugation or thread structure applied to the outer surface. The reinforcing elements, which are embedded in the plastic material of the inner wall 18 in a shear-resistant manner, stabilize it against deformation when exposed to heat, since typical values for thermal expansion for steel are in the range of approximately 15.7 to approximately 17 * 10 ^-6 1/K , while, for example, unreinforced polypropylene (PP) has a thermal expansion in the range of approx. 130 to approx. 180 * 10 ^-6 1/K.

In this exemplary embodiment, the first and second plastic material can be selected from a polypropylene copolymer, which can also be foamed throughout the entire cross section of the spacer. The inner wall 18, the side walls 14, 16 and the outer wall 20 are preferably extruded as a unit.

The profile body 12 encloses a cavity 38, which only has through openings or perforations 40, which are arranged at regular intervals in the middle of the inner wall 18, with a space between the panes, which is formed by a spacer frame formed from the spacer 10 and two glass panes in the assembled state , communicates and thus absorbs any water vapor present or penetrating there, which is then bound by a drying agent which is housed in the cavity 38 (not shown).

The inner wall 18 is designed with a greater thickness in the areas in which the optional secondary reinforcing elements 34, 36 are arranged than in the remaining wall areas (projections 42, 44), although the thickness of the inner wall 18 is directly adjacent to the side walls 14 and 16 decreases again, so that wall sections with a smaller wall thickness can also be found there as joint points 46, 48.

Optionally, the inner wall can have one or more areas 49 in its cross section (dash-dotted contour), which have a reduced wall thickness compared to other areas, for example from approximately 0.3 mm to approximately 0.4 mm. In the area in which the through openings or perforations 40 are formed, the wall thickness is preferably not reduced and is, for example, approximately 0.9 mm.

2 shows a spacer 50 according to the invention according to a second exemplary embodiment with a profile body 52, which has a first and a second side wall 54, 56 arranged parallel to one another and spaced apart from one another, between which an inner wall 58 extends.

Parallel to the inner wall 58, an outer wall 60 extends from the first to the second side wall 54, 56, which has a central first wall section 62 arranged parallel to the inner wall 58 and second and third wall sections 64, 66 on both sides of the first wall section 62, which are in one Cross section seen in the axial direction of the profile body 52 (as shown here) is aligned at an obtuse angle to the first wall section 62 and to the adjacent side wall 54 or 56 and connects to them.

The wall area in which the first side wall 54 and the second wall section 64 of the outer wall 60 adjoin one another is designed with a smaller wall thickness to form a joint point 68. The second side wall 56 is also connected to the third wall section 66 of the outer wall 60 via a wall area with reduced wall thickness to form a joint point 70.

If necessary, the second and third wall sections 64, 66 can be connected to the first wall section 62 of the outer wall 60 via a wall region 71 with reduced wall thickness to form additional joint points (in the 2 shown as an example only at the bottom right at the transition from the third to the first wall section 66 or 62).

On the outer surface of the spacer 50 in the area from the side wall 54 over the outer wall 60 to the side wall 56 there is a one-piece primary reinforcing element ment 72 is provided, which simultaneously takes on the function of a vapor diffusion barrier.

In the case of the present second exemplary embodiment of a spacer 50, the primary reinforcing element 72 is designed as a stainless steel foil with a thickness of approximately 0.09 mm, the mechanical properties of which are sufficient to reinforce the spacer so that it can be used with conventional cold bending systems to form corner areas for Spacer frame is cold bendable.

Optionally, the exemplary embodiment of a spacer 50 according to the invention has a first and a second secondary reinforcing element 74, 76 embedded in the inner wall 58, which are preferably designed as metal wires with a corrugation or thread structure applied to the outer surface. The distance f of the centers of gravity or center points of the cross section of the secondary reinforcing elements 74, 76 to the respectively adjacent side wall 54 or 56 is preferably approximately 1 mm to approximately 5 mm, more preferably approximately 1 mm to approximately 3 mm.

The profile body 52 encloses a cavity 78, which is in communication with the environment only via through openings 80, which are arranged at regular intervals in the middle of the inner wall 58, i.e. in the assembled state of an insulating glass pane unit with the space formed between the panes.

Via these through openings or perforations 80, the cavity 78 of the profile body 52 with a space between the panes in the mounted state of the spacer 50 can accommodate any water vapor that may be present or penetrating there, which is then bound by a desiccant that is housed in the cavity 78 (not shown). become.

In this exemplary embodiment, the inner wall 58 is designed in two layers, with a layer 58a adjacent to the cavity 78 being formed in one piece with the side walls 54, 56 and the outer wall 60, for example made of polypropylene copolymer, while the outer layer 58b is preferably made of a Colored polypropylene homopolymer made according to customer requirements, in particular co-extruded with the inner layer 58a. The secondary reinforcing elements 74, 76, if present, lie approximately half in the outer and inner layers 58b and 58a, respectively.

In the event that the profile body 52 is designed with a porous structure, the layer 58a adjacent to the cavity 78 can also be designed to be porous, for example foamed, while the outer layer 58b is preferably designed to be compact and not foamed.

The inner wall 58 is in turn designed with a greater thickness in the areas in which the secondary reinforcing elements 74, 76 are arranged than in the remaining wall areas (projections 82, 84), although the thickness of the inner wall 58 is directly adjacent to the side walls 54 and 56 decreases again, so that wall sections with a smaller wall thickness can also be found there as joint points 86, 88. In the central area in which the perforations 80 are provided, the wall thickness will preferably be approximately 0.9 mm.

3 shows a spacer 100 according to the invention according to a third exemplary embodiment with a profile body 102, which has a first and a second side wall 104, 106 arranged parallel to one another and spaced apart from one another, between which an inner wall 108 extends.

Parallel to the inner wall 108, an outer wall 110 extends from the first to the second side wall 104, 106, which has a central first wall section 112 arranged parallel to the inner wall 108 and second and third wall sections 114, 116 on both sides of the first wall section, which are in cross section Viewed from the axial direction of the profile body 102 (as shown here), an obtuse angle is aligned with the first wall section 112 and with the adjacent side wall 104 or 106 and connects to them.

The wall area in which the side wall 104 and the second wall section 114 of the outer wall 110 adjoin one another is designed with a smaller wall thickness to form a joint point 118. The second side wall 106 is also connected to the third wall section 116 of the outer wall 110 via a wall area with reduced wall thickness to form a joint point 120.

On the outer surface of the spacer 100, in an area that extends from the side wall 104 over the outer wall 110 to the side wall 106, a one-piece primary reinforcing element 122 is again provided, which at the same time takes on the function of a vapor diffusion barrier.

Optionally, the spacer 100 according to the invention has a first and a second secondary reinforcing element 124, 126 embedded in the inner wall 108, which are shown here as a flat Wires made of metal with a corrugation applied to the outer surface are designed for shear-resistant anchoring in the surrounding plastic material.

The profile body 102 encloses a cavity 128, which is in communication with the environment only via through openings or perforations 130 which are arranged at regular intervals in the middle of the inner wall 108.

Via these through openings 130, the cavity 128 of the profile body 102 can communicate with a space between the panes in the mounted state of the spacer 100 and thus absorb any water vapor that may occur there, which is then bound by a drying agent that is housed in the cavity 128 (not shown).

The inner wall 108 is formed with a greater thickness in the areas in which the secondary reinforcing elements 124, 126 are arranged than in the remaining wall areas (projections 132, 134), although the inner wall 108 is adjacent to the side walls 104 and 106 as the is formed with a smaller wall thickness, as well as in the central area of the inner wall in which the perforations 130 are provided.

Furthermore, the first wall section 112 of the outer wall 110 has wall regions 136, 138 with a reduced wall thickness, opposite the positions of the secondary reinforcing elements 124, 126 arranged in the inner wall 108, the contour of which essentially corresponds to the contour of the projections 132, 134. Preferably, the projections 132, 134 are dimensioned such that the wall thickness of the inner wall 108 in these areas is chosen to be approximately 50% larger than the thickness of the secondary reinforcing elements 124, 126. The wall thickness of the outer wall 110 in the area of the recesses 136, 138 is correspondingly reduced. This makes it easier to form corner areas when cold bending the spacer, in which parts of the inner wall 108 come into contact with parts of the outer wall 110.

4 shows a further spacer 150 according to the invention according to a fourth exemplary embodiment with a profile body 152, which has a first and a second side wall 154, 156 arranged parallel to one another and spaced apart from one another, between which an inner wall 158 extends.

Parallel to the inner wall 158, an outer wall 160 extends from the first to the second side wall, which, unlike the previously described embodiments of the spacer according to the invention, does not have a central first wall section made of plastic material and arranged parallel to the inner wall 158. However, as before, there are second and third wall sections 164, 166 made of plastic material, which are aligned at an obtuse angle to the adjacent side wall 154, 156 when viewed in cross section with respect to the axial direction of the profile body 152 (as shown here) and connect to them.

The wall area in which the side wall 154 and the second wall section 164 of the outer wall 160 adjoin one another is designed with a smaller wall thickness to form a joint point 168. The second side wall 156 is also connected to the third wall section 166 of the outer wall 160 via a wall area with reduced wall thickness to form a joint point 170.

On the outer surface of the spacer 150, in an area that extends from the side wall 154 via the second and third wall sections 164, 166 of the outer wall 160 to the side wall 156, a one-piece primary reinforcing element 172 is provided, which in addition to the function of a vapor diffusion barrier bridges the distance between the second and third wall sections 164, 166 of the outer wall 160 and thus additionally takes on the function of a first wall section 162.

Also in the case of the present fourth exemplary embodiment of a spacer 150, the primary reinforcing element can be designed as a stainless steel foil with a thickness of approximately 0.09 mm despite its additional function as a first wall section 162, and its mechanical properties are sufficient to also support this type of spacer according to the invention 150 to be reinforced so that it can be cold-bent with conventional cold bending systems to form corner areas. Here too, material savings and a lower weight of the profile body are achieved without the mechanical properties of the spacer 150 being affected.

Optionally, this exemplary embodiment of a spacer 150 according to the invention can also have a first and a second secondary reinforcing element 174, 176 embedded in the inner wall 158, which are preferably designed as metal wires (here in the form of a flat wire) with a corrugation applied to the outer surface.

The profile body 152 encloses a cavity 178, which only has through openings 180 which are at regular intervals in the middle of the Inner wall 158 are arranged, is in communication with the environment.

The inner wall 158 is formed with a greater thickness in the areas in which the secondary reinforcing elements 174, 176 are arranged than in the remaining wall areas (projections 182, 184), although the thickness of the inner wall 158 is directly adjacent to the side walls 154 and 156 decreases again, so that wall sections with a smaller wall thickness can also be found there as joint points 168, 170. Since the outer wall 160 in the area of the first wall section 162 is formed solely by the first reinforcing element 172, the formation of recesses to accommodate the projections 182, 184 is unnecessary due to the smaller wall thickness.

If necessary, the inner wall 158 can also be designed in two layers, as shown in FIG 4 is indicated by the dividing line 186. The secondary reinforcing elements can then be completely integrated into the external layer, as shown here.

Due to the assumption of the function of the first wall section 162 of the outer wall 160 by the first reinforcing element 172, in addition to the advantages already mentioned above, an additional space gain is achieved for the cavity 178, so that with the same size, this spacer 150 according to the invention, compared to the spacer 100 of the 3 , can absorb a larger amount of desiccant and thus provide increased drying capacity.

5 shows a further spacer 200 according to the invention according to a fifth exemplary embodiment with a profile body 202, which has a first and a second side wall 204, 206 arranged parallel to one another and spaced apart from one another, between which an inner wall 208 extends.

Parallel to the inner wall 208, an outer wall 210 extends from the first to the second side wall, which has a central wall section 212 arranged parallel to the inner wall 208 and second and third wall sections 214, 216 on both sides of the first wall section, which in a cross section to the axial direction of the profile body seen (as shown here) are aligned at an obtuse angle to the first wall section 212 and to the adjacent side wall 204, 206 and connect to them.

The wall area in which the side wall 204 and the second wall section 214 of the outer wall 210 adjoin one another is designed with a smaller wall thickness to form a joint point 218. The second side wall 206 is also connected to the third wall section 216 of the outer wall 210 via a wall area with reduced wall thickness to form a joint point 220.

On the outer surface of the spacer 200, in an area that extends from the side wall 204 over the outer wall 210 to the side wall 206, a one-piece primary reinforcing element 222 is provided, which simultaneously takes on the function of a vapor diffusion barrier.

Optionally, the exemplary embodiment of a spacer 200 according to the invention also has a first and a second secondary reinforcing element 224, 226 embedded in the inner wall 208, which are preferably designed as metal wires with a circular cross section and with a corrugation or thread structure applied to the outer surface.

The profile body 202 encloses a cavity 228, which is in communication with the environment only via through openings 230 which are arranged at regular intervals in the middle of the inner wall 208. The cavity 228 is used to hold desiccant.

The inner wall 208 is formed with a greater thickness in the areas in which the secondary reinforcing elements 224, 226 are arranged than in the remaining wall areas (projections 232, 234), although the thickness of the inner wall 208 is directly adjacent to the side walls 204 and 206 decreases again, so that wall sections with a smaller wall thickness can also be found there as joint points 236, 238.

In addition, the wall areas that form the transition between the second and the first wall sections 214, 212 and between the third and the first wall sections 216, 212 of the outer wall 210 are reduced in their wall thickness and thus form further joint points 240, 242, which go beyond that also bring about an improvement in the heat transfer resistance.

To further improve the heat transfer resistance, it can be provided that additional areas 244, 246 of the first wall section 212 of the outer wall 210 have reduced wall thicknesses, for example in the range of approximately 0.3 mm to 0.4 mm, which face the cavity 228 Side are designed as recesses.

The areas with reduced wall thickness additionally create a slightly increased volume of the cavity 228; this also applies to the joint points 218, 220, 236, 238, 240, 242, which may compensate or even compensate for the volume fraction of the cavity 228 that is reduced by the projections 232 and 234 can overcompensate.

This applies not only in connection with this exemplary embodiment, but generally for all exemplary embodiments in which joint points and/or wall areas with reduced wall thickness are present in the form of recesses formed on the cavity side.

6 finally shows a spacer 250 according to the invention according to a sixth exemplary embodiment with a profile body 252, which has a first and a second side wall 254, 256 arranged parallel to one another and spaced apart from one another, between which an inner wall 258 extends.

Parallel to the inner wall 258, an outer wall 260 extends from the first to the second side wall 254, 256, which has a first (middle) wall section arranged parallel to the inner wall 258 and second and third wall sections 264, 266 on both sides of the first wall section, which are in one in Cross section seen in the axial direction of the profile body 252 (as shown here) are aligned at an obtuse angle to the first wall section 262 and to the adjacent side wall 254, 256 and connect to them.

On the outer surface of the spacer 250, in an area that extends from the side wall 254 over the outer wall 260 to the side wall 256, a one-piece primary reinforcing element 272 is provided, which at the same time takes on the function of a vapor diffusion barrier.

In the case of the present sixth exemplary embodiment of a spacer 250, the primary reinforcing element is designed as a stainless steel foil with a thickness of approximately 0.09 mm, the mechanical properties of which are sufficient to reinforce the spacer so that it can be cold-bent using conventional cold bending systems to form corner areas .

Optionally, the exemplary embodiment of a spacer 250 according to the invention also has rovings 274, 276, 278, 280 embedded in the inner wall 258 and the outer wall 260, which are formed, for example, in a fleece-like manner from glass fibers.

Such rovings can also be provided with the reference numbers 282, 284, 286, 288 in 6 shown in the outer wall 260, in particular in the first wall section 262 are incorporated.

The profile body 252 encloses a cavity 290, which is in communication with the environment only via through openings 292 which are arranged at regular intervals in the middle of the inner wall 258.

Via these through openings 292, the cavity 290 of the profile body 252 can communicate with a space between the panes in the mounted state of the spacer 250 and thus absorb any water vapor that may occur there, which is then bound by a drying agent that is housed in the cavity 290 (not shown).

While in the embodiments of the spacers 10, 50, 100, 150 and 200 according to the invention 1 until 5 the primary reinforcing elements 32, 72, 122, 172 and 222 are integrated flush into the respective profile body, the primary reinforcing element 272 of the spacer 250 is the 6 placed on the surface of the profile body 252.

The transitions of the side walls 254, 256 to the second and third wall sections 264, 266 of the outer wall 260 can optionally be designed with larger wall thicknesses, as shown in this exemplary embodiment, in order to adapt the cross section of the cavity 290 to existing corner connectors that are used if The spacers are not bent into frames using the cold bending process, but are cut to the frame dimensions and connected to each other in the corner areas via a plug-in connection.

The clamping connection of the spacers relative to the corner connectors can be further improved if - as shown in this exemplary embodiment - one or two ribs 294, 296 are provided on the side walls 254, 256, which protrude into the cavity 290 from the side walls 254, 256. If necessary, further ribs (not shown) projecting into the cavity 290 can also be provided on the first wall section 262 of the outer wall.

QUOTES INCLUDED IN THE DESCRIPTION

This list of documents listed by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• US 4719728 [0003]
• WO 2014/005950 A1 [0003]
• DE 102010049806 A1 [0003]

Claims (26)

Spacer for insulating glass panes, comprising a profile body with a substantially rectangular cross-section and designed as a closed hollow profile, the profile body having a first and a second side wall arranged parallel to one another and spaced apart from one another, an inner wall extending between the first and the second side wall and an inner wall extending from the first outer wall extending to the second side wall and spaced from the inner wall, the outer wall having a first wall section aligned essentially parallel to the inner wall and second and third wall sections arranged on both sides of the first wall section, the latter at an obtuse angle when viewed in cross section perpendicular to the axial direction of the profile body are aligned with the first wall section and the respectively adjacent side wall and connect to these, wherein at least the inner wall, the first and the second side walls as well as the second and the third wall sections of the outer wall are manufactured using a first plastic material, and wherein the spacer is one of comprises a one-piece primary reinforcing element extending from the first side wall over the outer wall to the second side wall, which is designed as a vapor diffusion barrier, characterized in that the profile body in the wall areas in which the second and third wall sections of the outer wall are attached to the first and second Connect side wall, has a reduced wall thickness to form joint points. Spacer after Claim 1 , characterized in that the second and third wall sections are planar. Spacer after Claim 1 or 2 , characterized in that the primary reinforcing element is designed as a metal foil, in particular as a stainless steel foil, which preferably has a thickness of approximately 0.1 mm or less, in particular approximately 0.09 mm or less. Spacer after one of the Claims 1 until 3 , characterized in that the profile body is porous, in particular closed-pore, at least in partial areas of the inner and outer walls. Spacer after one of the Claims 1 until 4 , characterized in that the outer wall is partially formed by the primary reinforcing element, preferably at least the first wall section of the outer wall being formed essentially completely by the primary reinforcing element. Spacer after one of the Claims 1 until 4 , characterized in that the first wall section of the outer wall is made of a second plastic material, wherein the second plastic material of the first wall section of the outer wall is preferably compatible or identical to the first plastic material, wherein further preferably the first wall section of the outer wall is formed in one piece with the profile body, in particular is extruded, and wherein optionally the profile body is designed with a reduced wall thickness in the wall areas in which the first wall section of the outer wall adjoins the second and third wall sections to form joint points. Spacer after one of the Claims 1 until 6 , characterized in that the wall areas designed as joint points are designed as grooves on the inside of the hollow profile or on the outside of the profile body. Spacer after one of the Claims 1 until 7 , characterized in that in the inner wall a first and a second secondary reinforcing element is arranged parallel to the axial direction of the spacer profile, wherein the first secondary reinforcing element is arranged in a first section of the inner wall adjacent to the first side wall, and wherein the second secondary reinforcing element is arranged in a second section of the inner wall is arranged adjacent to the second side wall. Spacer after Claim 8 , characterized in that the area ratio of the cross-sectional area of the first to the sum of the cross-sectional areas of the secondary reinforcing elements is approximately 1:1 to approximately 4:1. Spacer after Claim 8 or 9 , characterized in that the secondary reinforcing elements have a distance from the respective side walls which corresponds to approximately 10 to approximately 40%, preferably approximately 30 to approximately 35% of the distance between the side walls. Spacer after Claim 8 or 9 , characterized in that secondary reinforcing elements are arranged in the inner wall at a distance of approximately 1 mm to approximately 5 mm, preferably from approximately 1 mm to approximately 3 mm, from the respective adjacent side wall. Spacer after one of the Claims 8 until 11 , characterized in that the secondary ary reinforcing elements are wire-shaped. Spacer after one of the Claims 8 until 12 , characterized in that the inner wall in the area of the secondary reinforcing elements has projections which extend into the cavity of the hollow profile and which have a greater wall thickness than the adjacent areas of the inner wall, the greater wall thickness preferably being approximately the sum of the thickness of the secondary reinforcing elements, vertically measured to the surface of the inner wall and corresponds to the thickness of the adjacent areas of the inner wall. Spacer after one of the Claims 8 until 13 , characterized in that the outer wall in the areas that lie opposite the sections of the inner wall receiving the secondary reinforcing elements has a recess which is in particular complementary to the thickening of the areas of the inner wall, and preferably has a depth of approximately half corresponds to the thickness of the secondary reinforcing elements. Spacer after one of the Claims 8 until 14 , characterized in that the surface of the secondary reinforcing elements is structured, in particular knurled, grooved or provided with a thread structure, and / or is equipped with an adhesion promoter layer. Spacer after one of the Claims 1 until 15 , characterized in that the first plastic material is based on polyolefin, in particular polypropylene (PP), polycarbonate (PC), polyvinyl chloride (PVC), styrene-acrylonitrile copolymer (SAN), polyphenylene ether (PPE), polyester, in particular polyethylene terephthalate (PET), polyamide (PA) or acrylonitrile-butadiene-styrene copolymer (ABS) or blends of two or more of these materials. Spacer after one of the Claims 1 until 16 , characterized in that the weight ratio of the weight of the primary reinforcing element to the weight of the plastic material is approximately 1:0.75 to approximately 1:3. Spacer after one of the Claims 1 until 17 , characterized in that the first plastic material and optionally the second plastic material have a reinforcing fiber content of approximately 5% by weight or more and approximately 20% by weight or less, in particular approximately 10% by weight or less , amounts. Spacer after one of the Claims 1 until 17 , characterized in that the first and optionally the second plastic material is free of reinforcing fibers. Spacer after one of the Claims 1 until 19 , characterized in that the first and/or the second plastic material comprises additives, in particular selected from fillers, pigments, light stabilizers, impact modifiers, antistatic agents and/or flame retardants. Spacer after one of the Claims 8 until 20 , characterized in that the thickness of the inner wall directly adjacent to the side walls is reduced compared to the area of the inner wall adjoining it in the direction of the profile center, the first and second secondary reinforcing elements preferably being arranged with their cross section completely in the area of the inner wall. Spacer after one of the Claims 8 until 21 , characterized in that the primary reinforcing element, which is arranged in the area of the outer wall or partially forms it, has a greater elongation at break than the secondary reinforcing elements arranged in the area of the inner wall. Spacer after one of the Claims 8 until 22 , characterized in that the first and second secondary reinforcing elements are each arranged adjacent to a part of the hollow volume of the hollow profile, in which after bending the hollow profile by 90 ° about a bending axis running perpendicular to the longitudinal direction and parallel to the inner wall, the inner wall and the outer wall are separated from each other are spaced apart. Spacer after one of the Claims 1 until 23 , characterized in that the hollow profile has a neutral axis perpendicular to the longitudinal direction and parallel to the inner wall when bent, which lies in the range of approximately 40% to approximately 60% of the total height of the hollow profile. Spacer after one of the Claims 1 until 24 , characterized in that the profile body has an overbending angle for producing a section bent through 90°, which is approximately 20° or less, preferably approximately 15° or less. Spacer after one of the Claims 1 until 25 , characterized in that the inner wall and / or the first, and / or second and third wall sections of the outer wall at least in one or more areas of the profile formed from the first and / or second plastic material fil cross-section have a wall thickness in the range of approx. 0.3 mm to approx. 0.7 mm.

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