DE202015105146U1 - Polygonal spacer frames and spacer profiles for the production of such frames - Google Patents

Abstract

A polygonal spacer frame having three or more corner portions for insulating glass sheets or the like, made of a spacer profile made on the basis of an elastically plastically deformable plastic material by: arranging a portion of the spacer profile in a heating device; - Heating the portion of the spacer profile or parts thereof to a predetermined temperature near the melting point of the material of the profile or the parts thereof; Bending the spacer profile in the region of the section to form a corner region of the frame; and - cooling the section.

Description

The invention relates to polygonal spacer frames with three or more corner areas, as used for example for the production of insulating glass, insulating glass systems, glass panels, especially for glass facades of buildings or the like, to two disks defined to form a disc space spaced from each other into a unit to assemble. As a spacer profiles produced profiles are used based on elastically-plastically deformable plastic material.

The invention further relates to spacer profiles, as they can be used particularly advantageous in the production of the polygonal spacer frame. The invention finally relates to insulating glass panes, facade elements and the like, which have been produced using the aforementioned spacer frame.

Conventionally, for the production of insulating glass panes or the like, mainly metal hollow profiles are used as spacers and processed as bar stock on bending machines into spacer frames that hold the glass panes of the insulating glass panes at their edge regions at a predetermined distance.

However, the metal profiles have a high thermal conductivity, which is why it has been proposed on various occasions to replace them with profiles made of plastic material.

In the preparation of the spacer frame made of plastic profiles, the plastic profiles are cold or alternatively bent by means of hot air to polygonal frame with corner areas on the existing bending machines, which leads to problems due to the high resilience of the plastic. These problems result in particular in disturbing deformations of the plastic profile and / or in impermissible deviations, especially in the corner areas, but also in the frame leg lengths. Furthermore, the high expenditure of time and the lack of reproducibility in the bending process are to be criticized.

From the German patent applications DE 198 05 348 A1 and DE 198 07 454 A1 Plastic spacers in the form of hollow profiles are known which contain embedded metal reinforcing elements over the entire length of the profiles, which are to push back the elastic springback effect of the plastic material during the bending process for the formation of corner regions.

However, it has been shown that the introduction of such in the longitudinal direction of the profiles continuous reinforcing elements in the manufacturing process, in particular in the profile extrusion is indeed possible, but requires an increased tool and equipment costs. In addition, the production process itself is prone to failure, the output of the manufacturing process is reduced compared to the extrusion of comparable conventional plastic profiles and observed a higher reject rate.

In addition, it is found that occur during cold bending in practice in the corner areas material detachments, cracks, bulges and / or indentations, even if it is tried over heat supply to counteract disturbing deformations. In addition, recovery effects that exceed the tolerable range are observed.

In addition, the continuous longitudinally embedded profiles of the metallic reinforcing profiles increase the thermal conductivity of the spacers and cause higher material costs. But this is a large part of the expected benefits of the plastic profile spacers destroyed again.

In the DE 199 61 902 A1 the proposal is made, instead of continuously embedded reinforcing elements only at the corners to be formed sections of the profile reinforcing elements, preferably made of metal, and to bend them together with the plastic profile or bend.

In practice, however, shows that when a heating of the plastic profile by means of hot air in the section to be bent and the concomitant softening and increased deformability of the material disturbing deformations and dimensional and angular deviations are lower, but still not a quality standard is achieved , which is the prerequisite for a low-reject, reproducible industrial production.

Object of the present invention is therefore to propose polygonal spacer frames, which can be made of plastic profiles substantially without reset and in particular also accurate and reproducible.

This should be able to work in particular with conventional, designed for the spacer frame of metal profiles bending machines.

This object is achieved according to the invention in the spacer frame described above by the features of claim 1.

Due to the heating of the material of the profile or parts thereof to a temperature close to the melting temperature before bending to form the corner region, the latter takes place under conditions in which, on the one hand, a very precise shaping of the corner region is reproducibly possible and at the same time a substantially restoring or relaxation-free deformation can be made. Nevertheless, the shape retention of the profile otherwise does not suffer. In addition, due to the heating carried out to the predetermined temperature close to the melting temperature, the deformation proceeds with little damage.

Due to preferred selected heating methods or devices, namely induction, resistance, ultrasonic, infrared or high frequency heating devices, in a relatively short time, i. in the range of a few seconds, either the profile in the entire cross section or selected parts thereof are brought to a temperature close to the melting temperature of the material of these profile parts. This rapid heating allows heating to temperatures close to the melting point without fear of undesirable deformation of the profile as a whole.

Even if the predetermined temperature is based on the properties of parts of the profile, it is preferably chosen so that it is also in the vicinity of the melting temperature of the plastic of the spacer profile.

In the exact determination of the predetermined temperature, it will be preferred to ensure that at this temperature, the respective plastic material of the profile completes the deformations imposed in the formation of the corner areas without breakage and in particular remain in the plastic material no appreciable residual stresses that lead to no longer tolerable reset effects could.

The cooling of the section is preferably carried out as forced cooling, in particular in the position-fixed corner region. This not only shortens the process of forming the corner, but also ensures that the corner is preserved with the exact dimensions. Furthermore, this procedure also allows the heating to temperatures very close to the melting point and even to the melting point of the material itself, without the dimensional stability disturbing flow of the material would be feared.

The plastic profiles used in the invention may be solid profiles. Preferably, however, they are formed as hollow profiles which form one or more longitudinally continuous chamber (s) for receiving desiccant, which keep the space formed between the glass panes dry and fog-free.

In the case of induction or resistance heating, one (or more) heating element (s) is embedded in the plastic profile and / or placed in the heater together with the portion of the profile. Here, the heating effect is achieved directly in or on the material of the profile, depending on whether the heating elements are embedded in the profile or positioned adjacent to the surface. The heat generated in the heating element is transferred directly to the plastic of the profile. Therefore, these methods are particularly preferred in the context of the present invention.

The heating elements may be sectoral, i. sections, be present or extend over the entire length of the profile. For example, consistently embedded in the profile heating elements can simultaneously form and use as reinforcing elements, so that the deflection of the profiles in the longitudinal direction, which can sometimes lead to problems in processing in the plastic profiles, is reduced to a tolerable level. Compared with the spacers described above with metal reinforcing elements can be used with significantly lower effective cross sections of the heating elements, so that the advantages of higher thermal resistance are maintained.

The sectoral heating has the advantage that the heat is concentrated on the corner region to be formed and that a short solidification time after the end of the bending process can be realized due to the comparatively low heated masses.

The sectorally used heating elements are held in heat-conducting contact with the profile section during the step of heating. Depending on the type of heating element, this may remain in the corner region of the spacer frame and, for example, provide for reinforcement thereof or be detached and removed from the profile section after the end of the heating step. This applies to both the induction and the resistance heating elements.

For induction heating, an electromagnetically activatable material is used as a heating element and preferably embedded in the plastic profile. About the action of an induction field can then the heating element and its Environment within seconds to the desired temperature.

Heaters suitable for both induction and resistance heating are metal foils, metal profiles, metal fibers, carbon fibers, carbon powders, metal powders, carbon and metal wires, metallized or otherwise conductive plastic fibers and / or foils.

Preferably, spacer profiles are used, which are designed in several parts. This particularly opens up the possibility of introducing heating elements sectorally into the profile section and in particular of introducing them so that they can remain permanently in the formed corner area.

When using the multipart profiles measures are also possible in a simple manner, which counteract a material constraint in the region of the corner formed. For example, recesses or recesses may be provided in a part of the profile, in which plastic material of the profile can be displaced during bending.

The profiles used according to the invention can be provided with so-called joining zones, in which joining surfaces, depressions, elevations, knurls, recesses and the like can be formed. These serve as or form a receptacle for the material displacements arising during bending, which in turn can act as a return stop after the cooling of the formed corner regions.

If multi-part spacer profiles are used, their parts can hereby be connected to the overall profile.

Here are also for the temporary assembly of the profiles (especially releasable) snap connections, which provide a positive connection between the profile parts, which may be created only in the corner areas a material and / or further, non-releasable positive connection.

This has the advantage that the part or parts of the profile lying on the outer bending radius have a relative longitudinal displaceability with respect to profile parts which are arranged on the inner radius, so that lower material constraints occur during the production of the corner regions.

Profiles are also preferably used in the inventive spacer frame in which a so-called auxiliary welding element is present. The auxiliary welding element has a melting temperature below the melting or softening point of the plastic material of the profile. When the section is heated to a temperature close to the melting point of the plastic material of the profile, the material of the welding auxiliary element will then already be molten.

This can be exploited in several ways. On the one hand, a corresponding compatibility of the material of the auxiliary welding element with the plastic material of the profile is provided, an intimate cohesive connection between the different parts of a multi-part profile produced. On the other hand, the molten material of the welding auxiliary element can escape into zones of expected material accumulation and material compression and create space for nachdrängendes plastic material of the profile. Furthermore, with appropriate design of the plastic profile, the material of the welding auxiliary element in recesses or recesses flow in which it acts as a lock against restoring forces during cooling and solidification, and thus the dimensional stability, in particular the predetermined angle of the corner area, improve.

In this context, welding auxiliary elements are particularly preferably formed from a material which is also recommended for the heating elements used in the induction and resistance heating methods. Here then the function of auxiliary welding element and heating element can be combined in one element.

In the induction heating method as well as the resistance heating method, a material is incorporated into the spacer profile or used in direct contact with the plastic material of the profile, with which the heat required for the desired heating is generated directly in or on the section of the profile to be bent, without it would require a transport of heat from a lying outside the profile heat source to the plastic material to be deformed. The heating can therefore take place in seconds, which contributes significantly to the efficiency of the method according to the invention.

In induction heating, an electromagnetically activatable material is preferably incorporated into the profile, which is then heated by an induction field.

Such electromagnetically activatable materials, which may be incorporated into the profile over the entire cross-section or selected cross-sectional areas, may be selected from oxide particles, metal powders and fibers, metal wires, metal wire meshes, braids, foils, and the like, as well as conductive blacks. Carbon fibers, fiber braids, metallized plastic films or metallized plastic or glass fibers. The electromagnetically activatable materials are heated by hysteresis and / or eddy current losses that occur in a medium to high frequency magnetic field generated by the heater. The resulting heat is directly available for delivery to the surrounding plastic material at the locations of the profile where the thermal energy is needed to increase the material temperature of the plastic, which is itself indifferent to the alternating fields. The electrical energy is thus transmitted via the magnetic field into the workpiece and converted there directly into the portion of the workpiece to be heated in heat energy. Again, this subarea can be defined simply and effectively via the distribution of the electromagnetically activatable materials over the profile cross-section from the outset.

The essential elements of an induction heating apparatus are a medium or high frequency generator, an induction coil and the workpiece to be heated, i. the portion of the spacer profile to be heated. With the help of the generator, an alternating voltage is generated, with which by means of the induction coil, an alternating electromagnetic field is generated. By introducing or arranging the portion of the spacer profile to be heated into the alternating field, an alternating current is induced in the electromagnetically activatable material which causes a targeted heating by the intrinsic resistance of the electromagnetically activatable material without direct contact with the energy source.

The amount of heat generated can be controlled within tight limits, regardless of any fluctuations in the power supply.

By way of example, the use of so-called pyrometers via the measurement of the infrared light radiated from the workpiece and a control circuit which converts the pyrometer signal can exactly simulate any temperature profiles. The specified temperature profile depends on the choice of the plastic used for the production of the profile, the electrical conductivity of the electromagnetically activatable material, the profile geometry as well as the desired deformation of the profile in the formation of the corner regions for the spacer frame.

P

= Heizleistung [W],

K

= empirische Konstante für die gewählte Heizanordnung,

I(ind)

= Strom der Iduktionsspule [A],

µ

= relative Premeabilität des elektromagnetisch aktivierbaren Materials,

p

= spezifischer Widerstand des elektromagnetisch aktivierbaren Materials [Ωmm²/m] und

f

= Frequenz der Wechselspannung des Frequenzgenerators [Hz] ist.

The amount of heat or heating power to be supplied to the plastic spacer profile is given by the following equation: P = K * I ² (ind) * (μ * p * f) ^1/2 , in which

P

= Heating power [W],

K

= empirical constant for the selected heating arrangement,

I (ind)

= Current of the induction coil [A],

μ

= relative premeability of the electromagnetically activatable material,

p

= specific resistance of the electromagnetically activatable material [Ωmm ² / m] and

f

= Frequency of the AC voltage of the frequency generator [Hz].

δ

= Eindringtiefe [mm],

p

= spezifischer Widerstand des elektromagnetisch aktivierbaren Materials [Ω·mm²/m],

µ_γ

= relative Permeabilität des elektromagnetisch aktivierbaren Materials und

f

= Frequenz der Wechselspannung des Frequenzgenerators [Hz] ist.

The penetration depth of the electromagnetic field and thus the depth in the profile, in which an alternating current is generated in the electromagnetically activatable material, can be calculated as follows: δ = 503 (p / μ _γ · f) ^½ , in which

δ

= Penetration depth [mm],

p

= specific resistance of the electromagnetically activatable material [Ω · mm ² / m],

_μ γ

= relative permeability of the electromagnetically activated material and

f

= Frequency of the AC voltage of the frequency generator [Hz].

• – größtmögliche Reproduzierbarkeit des Erwärmungsvorgangs;
• – kurze Zykluszeiten;
• – spezifischer Wärmeeintrag, d.h. die Induktionswärme lässt sich gezielt einbringen, so dass selbst kleine Bereiche erwärmt werden können, ohne die Umgebung solcher Bereiche zu beeinträchtigen;
• – flexibler Aufbau der Heizvorrichtung, d.h. die Heizzonen können viele Meter entfernt vom Frequenzgenerator angeordnet werden;
• – umweltschonend, da keine schädliche γ-Strahlung, Abgase, Dämpfe, Lärm oder Verlustwärme erzeugt werden.

The particular advantages of induction heating are:

• - highest possible reproducibility of the heating process;
• - short cycle times;
• - Specific heat input, ie the induction heat can be targeted, so that even small areas can be heated without affecting the environment of such areas;
• - Flexible design of the heater, ie the heating zones can be located many meters away from the frequency generator;
• - Environmentally friendly, since no harmful γ-radiation, exhaust gases, vapors, noise or heat loss are generated.

Similar advantages can be achieved with the resistance heating method discussed above. By applying a heating voltage to an electrically conductive heating element, embedded on the outside and / or the inside and / or in the material of the plastic of the profile, the supplied electrical energy can be converted into heat in the acting as an ohmic resistance heating element. Here too, the arrangement of the heating element or elements in or on the profile can again influence the location of the generation of the heat in order to specifically heat only the areas and materials of the profile which are responsible for the heat Operation of forming a corner are necessary.

These and other advantages of the present invention will be explained in more detail below with reference to the drawing. They show in detail:

1a to 1c a schematic representation of the induction heating process according to the invention;

2 a schematic representation of the resistance heating method according to the invention;

3 a heating element which can be used in the method according to the invention; and

4 to 48 Embodiments of inventive spacer profiles.

In the 1a to 1c the induction heating according to the invention is shown schematically using the example of a multi-part spacer profile.

The spacer profiles used in the context of the present invention are preferably hollow profiles with a rectangular cross-section, which have two parallel side walls, to which the two glass panes are applied during assembly of the insulating glass system. The side walls are connected by two parallel legs, wherein the inner leg is oriented towards the space between the panes and the outer leg forms the outer edge of the assembled insulating glass system.

At the in 1a to 1c shown hollow profile comprises a first profile part 10 the outer thigh 12 and second profile part 14 the inner thigh 16 , The side walls 18 be through the two profile parts 10 and 14 formed together by an inner wall element 20 of the first profile part 10 between two parallel outer wall elements 22 of the second profile part 14 is inserted. In the 1a to 1c are just one of the side walls 18 as well as the adjacent areas of the two legs 12 and 16 shown in cross section.

The 1a shows the spacer profile before carrying out the induction heating method according to the invention. In the of the two outer wall elements 22 of the second profile part 14 formed gap is a along the second profile part 14 extending heating element 24 arranged so that the inner wall element 20 of the first profile part 10 initially not with its full length between the two outer wall elements 22 can be inserted. The heating element 24 consists of an electromagnetically activatable material and has a melting temperature which is below the softening temperature of the two profile parts 10 and 14 so that it simultaneously serves as a welding auxiliary element when carrying out the induction heating method.

To carry out the method according to the invention, a section of the spacer profile is arranged in an induction heating device in which by means of an induction coil 26 a magnetic field in the region of the spacer profile can be generated.

In the 1b the spacer profile is shown during the induction, which is through the induction coil 26 generated magnetic field is indicated by concentric circular sections.

The magnetic field becomes the heating element 24 heated in the section in question within a short time to a predetermined, above its melting point temperature. As the material of the heating element 24 now in a molten state, it can act as a welding aid and the joints between the inner wall element 20 and the outer wall elements 22 fill out. At the same time the heating element causes 24 in the relevant section, a heating of the two profile parts 10 and 14 of the spacer profile to a temperature near its melting point, so that they soften and the spacer profile can be bent in the heated portion to form a corner region. By bending it comes to a compression of the two profile parts 10 and 14 so that the inner wall element 20 completely between the two outer wall elements 22 is pushed. This will cause the molten material of the heating element 24 displaced and even in the joints between the inner wall element and the outer wall elements 22 distributed.

After bending the spacer profile of this is removed from the induction heating and allowed to cool, preferably a forced cooling takes place at a fixed position corner area.

1c shows the cooled spacer profile after performing the method according to the invention. The hardened material of the heating element 24 is over the entire contact area between the first profile part 10 and the second profile part 14 distributed and forms a solid, cohesive connection between the two parts 10 and 14 ,

In the 2 the implementation of the resistance heating method according to the invention is shown schematically using the example of a one-piece spacer profile.

In the side walls 18 as well as the outer leg 12 the spacer profile is a continuous metal foil 28 embedded. Instead of the metal foil 28 However, other electrically conductive materials can be used here.

For carrying out the method according to the invention is a section 30 the spacer profile arranged in a resistance heater. The heater comprises three pairs of electrodes 32 , which with the metal foil 28 be brought into contact (indicated by arrows). To make this possible, have the side walls 18 and the outer thigh 12 at the two ends of the section 30 recesses on their outer surfaces 34 on, leaving the continuous metal foil 28 is accessible from the outside. At the recesses 34 at one end of the section 30 are each the anodes (+), at the recesses 34 at the other end of the section 30 in each case the cathodes (-) arranged.

When applying a voltage to the electrodes 32 gets in the metal foil 28 along the section 30 induces a current flow. The serving as a heating element metal foil 28 is heated and causes heating of the material of the spacer frame in the section 30 to a temperature near the melting point.

The spacer profile can now be in the section 30 bent to form a corner area. The inner thigh 16 in which no metal foil 28 is arranged in the method shown here is not or only to a lesser extent heated because it forms the inner radius in the bending process and therefore in comparison to the outer leg 12 and the side walls 18 less stressed.

The cooling of the spacer profile after bending takes place, as described above in connection with the induction heating method, preferably in position-fixed corner region.

3 shows a usable in the process according to the invention heating element, which can be removed after heating of the spacer profile of the corner region formed.

The heating element 36 includes a rectangular base 38 and two mutually parallel arranged approximately triangular side surfaces 40 , The heating element 36 For the implementation of the method according to the invention, a spacer profile is placed in the section of the corner region to be formed, wherein the heating element 36 is dimensioned so that its footprint 38 with the outer thigh 12 and its side surfaces 40 with the side walls 18 of the spacer profile are each in heat-conducting contact.

The spacer profile comes with the heating element 36 arranged in a heater and the heating element 36 heated by the induction or resistance heating method. In this case, there is the heating element 36 from an electromagnetically activatable or electrically conductive material.

After heating the spacer profile and the formation of the corner area, the heating element 36 removed from the spacer profile and cooled the formed corner area.

The 4 to 7 show embodiments of spacer profiles, which can be used in the method according to the invention and which are made using metal foils as heating elements.

These embodiments are closed hollow profiles, of which in the 4 to 7 only one of the side walls at a time 18 as well as in about half of the two thighs 12 and 16 are shown. The interior 42 the hollow section is covered with a desiccant 44 filled and the inner thigh 16 has breakthroughs 46 so that when assembled insulating glass element present in the space between the two panes of moisture through the desiccant 44 can be absorbed.

In the embodiment of the 4 are the outer surfaces of the side walls 18 and the outer thigh 12 with a metal foil 48 Mistake. In the area of the side walls 18 is the metal foil 48 with holes 50 provided, which fill in the production of the spacer profile with the plastic material of the profile and thereby to a stable connection between the metal foil 48 and the spacer profile.

In the embodiment of the 5 is the metal foil 48 on the outside of the outer thigh 12 attached and the other in the side walls 18 embedded.

An embodiment in which the metal foil 48 both in the side walls 18 as well as in the outer thigh 12 is embedded in the 6 shown. In addition, here is a wall portion of the hollow profile, the outer leg 12 with the side walls 18 connects, at an angle of 45 °.

7 shows an embodiment in which a perforated metal foil 48 both on the surface of the sidewalls 18 as well as embedded in this is arranged. The two layers of metal foil 48 are recommended here, as the side walls 18 are formed relatively thick.

In the embodiments of the 4 to 7 used metal foils 48 can act as both induction and resistance heating elements. Especially if the metal foil 48 At least partially disposed on the surface of the spacer profile, the resistance heating method offers, since the metal foil 48 Here without the formation of recesses can be brought into contact with the electrodes.

Is the metal foil 48 as in the embodiments of the 4 and 5 , on the outer surface of the outer thigh 12 In addition, it may additionally act as a vapor barrier which prevents moisture from diffusing through the material of the spacer profile. A vapor barrier can, regardless of acting as a heating element metal foil 48 be provided in all inventive spacer profiles, as for example in the 7 by a dash-dotted line along the outer leg 12 is indicated.

The 8th to 13 show details of spacer profiles according to the invention, in which metal profiles are embedded as heating elements in the plastic material of the spacer profile. Instead of metal profiles but also profiles of other, inductive or resistance-heated materials can be used. Shown in the 8th to 13 in each case a part of the outer leg 12 and one of the side walls 18 of the spacer profile in cross section. An optional vapor barrier is through one along the outer leg 12 running dash-dotted line indicated.

The embodiment of 8th includes an angle profile 52 that go along through the outer thigh 12 and the side wall 18 formed corner is embedded in the material of the spacer profile.

In comparison, the angle profile 52 in the embodiment of the 9 shifted so that the one leg of the angle profile 52 still in the side wall 18 embedded, the other leg, however, on the inner surface of the outer leg 12 the spacer profile rests. This part of the angle profile 52 includes breakthroughs 54 into which the material of the spacer profile penetrates during production.

In the embodiment of the 10 is the angle profile 52 disposed on the side of the cavity of the spacer profile and is located on the inner surfaces of the outer leg 12 and the side wall 18 at. Both legs of the angle profile 52 are with breakthroughs 54 provided in the manufacture of the plastic material of the spacer profile flows into and a positive connection with the angle profile 52 forms.

In the embodiment of the 11 is the angle profile 52 arranged on the outside of the spacer profile. Here is the angle profile 52 pressed into the material of the spacer frame, so that its outer surfaces with the outer surface of the side wall 18 or the outer leg 12 finish flush. Both legs of the angle profile 52 have breakthroughs 54 on, in which the material of the spacer profile flow and a positive connection with the angle profile 52 can form.

12 shows a further embodiment in which a round profile 56 For example, in the form of a wire, along the area in which the outer leg 12 and the side wall 18 abut, is embedded in the material of the spacer profile. In addition, here is a metal foil 48 in the sidewall 18 embedded.

The embodiment of 13 Compared to this modified by the fact that the round profile 56 in through the side wall 18 and the outer thigh 12 formed angle is clipped and there by two parallel protrusions 57 the side wall 18 and the outer thigh 12 is held.

In the embodiments of the 8th to 13 used metal profiles may be contained either in the entire spacer profile or only sectorally, ie in the sections in which corner regions of the spacer frame to be formed. A continuous arrangement of the profiles may be advantageous in that they not only function as heating elements, but also contribute as reinforcing elements to the stability of the spacer frame.

The 14 to 17 show embodiments of inventive spacer profiles are embedded in the metal fibers as induction heating. Instead of metal fibers, it is also possible to use carbon fibers, metal wires, carbon wires or metallized synthetic fibers in each case.

The embodiments of the 14 to 17 are each as hollow sections with two legs 12 and 16 and two side walls 18 formed, with only one side wall 18 and a portion of the two legs 12 and 16 is shown in the figures. The cavity 42 The profile comes with a desiccant 44 filled and the inner thigh 16 has breakthroughs 46 on. A possible Vapor barrier is by a dash-dotted line along the outer leg 12 indicated.

In the embodiment of the 14 are metal fibers running in the longitudinal direction of the spacer profile 58 only in the side wall 18 embedded.

By contrast, in the embodiment of the 15 metal fibers 58 also in the two thighs 12 and 16 contained, but in a lower concentration than in the sidewall 18 , By the respective concentration of the metal fibers 58 It can be determined how much the area in question heats up for a given magnetic field strength in the induction heating process. Metal fibers therefore offer the possibility of adapting the heating of the individual regions of the profile to the respective requirements in the bending process.

In the embodiment of 16 the spacer profile additionally comprises a central web 60 , the two thighs 12 and 16 connects together and the cavity 42 divided into two equal halves. This adds stability to the spacer profile. Both in the side walls 18 as well as in the Mittelsteg 60 are metal fibers 58 embedded.

In the embodiment of the 17 are the metal fibers 58 not directly in the material of the spacer profile, but in an insert element 62 embedded, which has a rectangular cross-section and in the interior of the widened side wall 18 extends. By a different melting point of the material of the insert element 62 In comparison to the material of the spacer profile, the bending behavior of the profile can be additionally influenced.

18 shows a further embodiment of a spacer profile with an inductive or resistance-heated heating element, for example in the form of a metal profile 64 with rectangular cross-section, in each side wall 18 embedded in the spacer profile. The metal profile 64 may be provided sectorally in the sections to be bent or continuously, to give the spacer profile additional stability.

The 19 to 22 show embodiments of spacer profiles, which can be used in conjunction with an additional heating element, which does not remain on the spacer profile, in the inventive method. The spacer profiles are designed as one-piece hollow sections, the additional, along the side wall 18 arranged reinforcing element 66 exhibit. This reinforcing element 66 on the one hand can increase the stability of the spacer profile overall, on the other hand improve the bending behavior of the spacer profile with a corresponding choice of material by a different melting point compared to the profile material and / or by a mobility relative to the profile.

In the embodiment of the 19 the reinforcing element runs 66 along the inner surface of the sidewall 18 , Along its two edges, the reinforcing element has respective cross struts 68 on which in the two thighs 12 and 16 of the spacer profile are embedded and thereby for a stable hold of the reinforcing element 66 to care.

The embodiment of 20 differs herefrom in that the reinforcing element 66 is formed in two parts.

The reinforcing element 66 is here in a plane parallel to the side wall 18 divided in the longitudinal direction, wherein the one part of the side wall 18 facing and the other part of the cavity 42 ,

In the embodiment of the 21 has the reinforcing element 66 a folded structure, so that, similar to the embodiment of the 20 , two parts of the reinforcing element 66 but here there is a bend in the outer leg 12 is embedded, interconnected. A crossbar 68 lies only at the edge of the reinforcing element opposite the bend 66 in front and is in the inner thigh 16 embedded.

In the embodiment of the 22 has the reinforcing element 66 a trapezoidal cross section. While a middle area of the reinforcing element 66 on the inside of the side wall 18 is applied, the two edge areas of the side wall 18 in the direction of the cavity 42 deposed and are in the thighs 12 and 16 embedded the spacer profile to the reinforcement. In through the side wall 18 and the thighs 12 and 16 formed corner areas created by cavities 70 , in which material can be displaced when bending the spacer profile.

Particularly suitable for the method according to the invention are also such spacer profiles, in which recesses or recesses are arranged in one or more parts of the profile. These serve to absorb displaced material in the formation of the corner area and thus counteract material constraints.

Such recesses in various sizes and arrangements are in the Embodiments of 23 to 31 realized. These embodiments in turn provide one-piece hollow sections with two side walls 18 and two thighs 12 and 16 some, some with a desiccant 44 filled cavity 42 enclose. Shown in each case one of the side walls 18 and portions of the two legs 12 and 16 ,

In the embodiment of the 23a has the side wall 18 a variety of recesses 72 on. At the recesses 72 These are cylindrical openings that extend over the entire inner surface of the side wall 18 are spread and away from the cavity 42 until about the middle of the side wall 18 extend. 23b shows a plan view of the inner surface of the side wall 18 ,

The 24 to 31 show embodiments of inventive spacer-holder profiles, in which recesses in or on an additional reinforcing element 66 are arranged. The different reinforcement elements 66 each extend along the side wall 18 between the two thighs 12 and 16 , If they are made of an appropriate material, the reinforcing elements 66 also serve as heating elements, alternatively, the respective spacer profiles but also with an additional heating element, as in connection with the 3 described to be used in the method according to the invention.

In the embodiment of the 24a lies the reinforcing element 66 directly on the inner surface of the side wall 18 and is in the thighs 12 and 16 embedded for reinforcement. The reinforcing element 66 has large gaps at regular intervals 72 in particular, which may also have an oval cross-sectional shape and along the central axis of the reinforcing element 66 are oriented in the longitudinal direction. 24a shows the reinforcing element 66 in a plan view from the side of the cavity 42 ,

The embodiment of 25 differs from this in that the recesses 72 have an elongated shape and each obliquely in the not in the legs 12 and 16 embedded region of the reinforcing element 66 extend. In the 25b is a plan view of the cavity-side surface of the reinforcing member 66 shown.

The embodiment of the 26 also includes one on the side wall 18 adjacent reinforcing element 66 , This is in the inner thighs 16 about one third of its thickness and in the outer leg 12 essentially completely embedded. The 26b . 26c and 26d show three different variants of the reinforcing element 66 in a side view in a opposite to the 26a reduced scale.

The reinforcing element 66 according to 26b has round recesses at regular intervals 72 on, on the outer thigh 12 facing edge of the reinforcing element 66 are open.

According to the embodiment of the 26c are the round recesses 72 from the edges of the reinforcing element 66 spaced and closed.

In the embodiment of the 26d are the recesses 72 again along the outer leg 12 facing edge of the reinforcing element 66 arranged and open at the side. The recesses 72 Here are trapezoidal, with the shorter side of the trapezoid represents a lateral opening.

The embodiment of 27 comprises a reinforcing element 66 with a U-shaped cross-sectional profile. This is the reinforcing element 66 as in 27a shown on the inner surface of the sidewall 18 and has two legs 74 in turn, on the inner surfaces of the thighs 12 and 16 abut the spacer profile. On the inner thigh 16 becomes the reinforcing element 66 through one with the thigh 74 of the reinforcing element 66 flush final projection 76 held, in the area of the outer thigh 12 through a thigh 74 of the reinforcing element 66 overlapping bracket 78 , recesses 72 can each be on the two thighs 74 of the reinforcing element 66 be formed.

Two variants of the reinforcing element 66 are in the 27b and 27c shown, each with a view of the thighs 74 is shown. In the embodiment of the 27b are round recesses 72 at regular intervals along the side wall 18 opposite edge of the thigh 74 arranged and open at the side. In the 27c are the round recesses 72 spaced from the edge of the reinforcing element in the direction of the side wall 18 offset and laterally closed.

In the embodiment of the 28 is the reinforcing element 66 along the inner surface of the sidewall 18 arranged and along its two edges for reinforcement in the reinforced thighs 12 and 16 embedded like out 28a seen.

In its edge regions, the reinforcing element 66 each longitudinally extending grooves 82 on, which are filled with the material of the spacer profile. Along its central axis has the reinforcing element 66 elongated recesses 80 with one on the side of the cavity 42 above edge 84 on. On both sides of the elongated recesses 80 are smaller round recesses 72 arranged at regular intervals.

When heating up and bending the spacer profile can be displaced material of the side wall 18 in the recesses 72 and 80 of the reinforcing element 66 flow in what is in the 28a already indicated. A plan view of sides of the cavity 42 out onto a portion of the reinforcing element 66 is in the 28b shown.

The embodiment of 29 has a similar reinforcing element 66 like that one 28 , The along the central axis of the reinforcing element 66 arranged recesses 80 have a round cross section and are slightly larger than the arranged on both sides of the longitudinal axis recesses 72 (see. 29a ). Along the areas where the recesses 72 are arranged, is the reinforcing element 66 slightly thinner than formed along the central region and the edge regions.

In the resulting gaps between the reinforcing element 66 and the side wall 18 are, at least partially, heating elements 86 arranged with a rectangular cross-sectional profile. Furthermore, in this embodiment, two more heating elements 88 provided with a round cross-sectional profile, the above and below the reinforcing element 66 in the thighs 12 and 16 are embedded. Due to the arrangement of the heating elements selected here 86 and 88 can in carrying out the induction heating according to the invention both to the side walls 18 and the thighs 12 and 16 as well as the reinforcing element 66 a defined amount of heat are delivered. In the 29b is a plan view of sides of the cavity 42 on a portion of the reinforcing element 66 and one of the heating elements 88 shown.

In the embodiment of the 30 is a reinforcing element 66 parallel to the side wall 18 but spaced parallel to this (see. 30a ). The reinforcing element 66 is along its edges for reinforcement in the thighs 12 and 16 embedded. It has a large number of round recesses 80 on, each on one side of the reinforcing element 66 ie either the side wall 18 or the cavity 42 facing, an edge 84 exhibit. 30b shows the reinforcing element 66 both in plan view and in cross section. When bending the spacer profile can be displaced material in both between the side wall 18 and the reinforcing element 66 formed cavity 70 as well as in the recesses 80 of the reinforcing element 66 incorporated.

31 shows an embodiment of a spacer profile with a two-part reinforcing element. The two parts 90 and 92 of the reinforcing element are each formed as profiled strips, which are parallel to the side wall 18 run and with a cross strut 94 for reinforcement in the thighs 12 respectively. 16 are embedded. That in the inner thigh 16 embedded first part 90 the reinforcing element has a longitudinally continuous groove 96 in which a longitudinally continuous spring 98 in the outer thigh 12 embedded second part 92 engages the reinforcing element. In the ground state of the spacer profile engages the spring 98 but only with a very small section in the groove 96 one. When bending the spacer profile according to the inventive method, however, the spring 98 in the formed corner area to a large extent in the groove 96 pushed in, whereby this corner region of the spacer frame is additionally stabilized.

In the 32 to 36 Embodiments of multi-part spacer profiles are shown. These spacer profiles are hollow profiles with a substantially rectangular cross section, which consists of a first profile part 10 and a second profile part 14 are composed. The first profile part comprises the outer leg 12 and one outside each 100 the side walls 18 while the second profile part 14 the inner thigh 16 and an inner part 102 the side walls 18 includes.

The exterior parts 100 and the internal parts 102 lie flat against each other and together form each a side wall 18 , where the outer part 100 on a lead 104 of the inner thigh 16 sits up and flush with this.

In the 32 to 36 is only one of the side walls 18 and in about half of the thighs 12 and 16 shown in cross section. An optional vapor barrier is by a dash-dotted line along the outer leg 12 indicated.

In the embodiment of the 32a has the outer part 100 that in the in 32b shown wave profile on. Through to the inner thigh 16 open recesses 106 a material constraint is counteracted during bending of the spacer profile. On the entire inner and outer surface of the outer part 100 is a metal foil 48 arranged, which can act as a heating element in the induction or resistance heating method. The metal foil 48 has holes 50 on, in the at the production of the spacer profile, the material of the first profile part 10 can flow in, creating an intimate connection with the metal foil 48 will be produced. The two profile parts 10 and 14 are joined by gluing along the contact surface of the outer part 100 and the inner part 102 ,

In the embodiment of the 33 is a serving as a heating metal foil 48 in all parts of the profile, ie in the two legs 12 and 16 as well as in the outer part 100 and the inner part 102 the side wall 18 embedded. The connection of the two profile parts 10 and 14 also takes place here by gluing.

In the embodiment of the 34 has the inner part 102 in the plan view of sides of the cavity 42 a wave profile on, as in the 34b is shown. By in the direction of the outer thigh 12 open recesses 106 Material constraints is counteracted when bending the spacer profile. As heating elements in this spacer profile in the longitudinal direction of the profile extending metal fibers 58 provided in the outer leg 12 adjacent third of the outer part 100 and in the inner leg 16 adjacent third of the inner part 102 are arranged. The two profile parts 10 and 14 are glued along their contact surfaces. For an alternative connection or additional stabilization of the connection between the two profile parts 10 and 14 can be a welding auxiliary element 108 be provided with a round cross-sectional profile. The welding aid element 108 is along the joining surface between the outer part 100 and the lead 104 of the inner thigh 16 embedded in these two elements and consists of a material with a lower melting point than the plastic material of the spacer profile. In carrying out the method according to the invention, therefore, it is already in the molten state during heating of the spacer profile and ensures an intimate cohesive connection between the two profile parts 10 and 14 in the corner region of the spacer frame to be formed. Depending on the material, the auxiliary welding element 108 also act as a heating element at the same time.

The embodiment of 35 is different from the one of 34 only in that the elongated recesses 106 in the inner part 102 are closed laterally. A top view of the inner part 102 from the side of the cavity is in the 35b shown.

In the embodiment of the 36 is the outer part 100 at its contact surface with the inner part 102 with a metal foil 48 provided (see. 36a ). The metal foil 48 serves as a heating element and has holes 50 on how this is related to the 32 has been described. The inner part 102 indicates in plan view ( 36b ) A wave profile with in the direction of the outer leg 12 open recesses 106 , As a result, material constraints when bending the spacer profile is counteracted. In the spacer profile of this embodiment are two auxiliary welding elements 108 provided along the joining surfaces between the outer part 100 and the lead 104 of the inner thigh 16 or between the inner part 102 and the outer thigh 12 are arranged. The welding auxiliary elements 108 correspond in their operation to that of the embodiment of 34 ,

The 37 to 40 show Ausührungsbeispiele inventive spacer profiles, which are also two-piece hollow sections. However, these differ from the embodiments of the 32 to 36 in that the first profile part 10 a connected to the outer leg inner wall element 20 comprising, which between two parallel outer wall elements 22 of the second profile part 14 , which with the inner leg 16 are connected, is inserted. The inner wall element 20 and the outer wall elements 22 together form the side wall 18 ,

In the embodiment of the 37a is in the space between the outer wall elements 22 a welding aid element 108 inserted with a round cross-sectional profile. When carrying out the method according to the invention, the welding auxiliary element melts 108 during the heating of the spacer profile and distributed evenly in the joints between the inner wall element 20 and the outer wall elements 22 , Upon cooling of the spacer profile, the material of the welding auxiliary element solidifies 108 again, thus forming a solid cohesive connection between the two profile parts 10 and 14 ,

If the welding auxiliary element 108 consists of an electromagnetically activatable material, it can also serve as a heating element in the induction heating according to the invention. To the welding auxiliary element 108 To make electromagnetically activatable, for example, finely divided metal particles can be embedded in the material. An alternative embodiment of a welding auxiliary element which simultaneously serves as a heating element 110 is in the 37b shown. This comprises an electromagnetically activatable core area 112 , For example, a metal wire, which acts as a heating element, and serving as a welding auxiliary sleeve 114 under the action of the core area 112 generated heat is melted.

In the embodiment of the 38 are each two band-shaped welding auxiliary elements 116 in the with the outer wall elements 22 in contact side surfaces of the inner wall element 20 embedded. The welding auxiliary elements 116 consist of a material that becomes fluid when heating the spacer profile and acts as an adhesive, the two profile parts 10 and 14 cohesively connects with each other.

39 shows a spacer profile after welding the two profile parts 10 and 14 by means of a welding auxiliary element 108 like the one in 37a shown embodiment. The strength of the connection between the two profile parts 10 and 14 is here additionally increased by the fact that the inner wall element 20 drilling 118 and that the cavity 42 adjacent outer wall element 22 at its the inner wall element 20 facing surface notches 120 having. The holes 118 and the notches 120 act as joining elements, in which the material of the auxiliary welding element 108 flows. During cooling and solidification of the material of the welding auxiliary element 108 So is a positive connection between the two profile parts 10 and 14 educated.

The embodiment of 40 corresponds to the one of 39 with the difference that in the outer thighs 12 and the inner wall elements 20 a metal foil 48 is embedded. The metal foil 48 acts in the inventive method as induction heating and leads to a heating, in particular of the inner wall element 20 , This is so close in the present case between the outer wall elements 22 fitted that soften the plastic material of the two profile parts 10 and 14 Even without the addition of a welding auxiliary element a cohesive connection between the inner wall element 20 and the outer wall elements 22 arises.

The embodiments of the 41 to 43 are two-piece spacer profiles, where the first profile part 10 the outer thigh 12 forms and the second profile part 14 the inner thigh 16 and the side walls 18 includes. In addition, these spacer profiles include one on the inner surface of the sidewall 18 adjacent reinforcing element 66 ,

In the embodiment of the 41 becomes the reinforcing element 66 by two on the inner surfaces of the legs 12 and 16 trained protrusions 76 fixed.

The two profile parts 10 and 14 and the reinforcing element 66 are glued together. The reinforcing element 66 has round recesses along its central axis 72 on, in the displaced when bending the spacer profile material can penetrate.

In the embodiment of the 42 becomes the reinforcing element 66 only on the inner leg 16 by a projection 76 fixed. Along the outer leg 12 facing edge of the reinforcing element 66 is a welding aid element 108 in the material of the first profile part 10 embedded. Another welding aid element 108 is along the contact surface between the outer leg 12 and the side wall 18 in the two profile parts 10 and 14 embedded.

In the manufacture of the spacer frame according to the invention cause the auxiliary welding elements 108 , which may be formed simultaneously as heating elements, a material connection between the two profile parts 10 and 14 and the reinforcing element 66 as related to the embodiment of the 34 has been described.

The reinforcing element 66 has elongated recesses at regular intervals 72 on, which are oriented in the transverse direction of the spacer profile. 42b shows a plan view of the reinforcing element 66 from the side of the cavity 42 out.

The embodiment of 43 differs from the previous embodiment in that the elongated recesses 72 of the reinforcing element 66 in the direction of the outer thigh 12 are open (cf. 43a ).

43b shows a plan view of the reinforcing element 66 from the side of the cavity 42 out.

The 44 to 46 show embodiments of multi-part spacer profiles, in which the outer leg 12 , the inner thigh 16 and the side walls 18 each form separate components of the profile. These spacer profiles also include a on the outer wall 18 adjacent reinforcing element 66 ,

In the embodiment of the 44 lie the thighs 12 and 16 each at the edges of the side wall 18 at. The reinforcing element 66 is along an edge for reinforcement in the inner leg 16 embedded, with its other edge it lies on the outer leg 12 and is by a lead 76 of the outer thigh 12 fixed. Along its central axis has the reinforcing element 66 round recesses 72 on, in the in the bending of the spacer profile displaced material can flow. The thigh 12 and 16 , the side wall 18 and the reinforcing element 66 are glued together at their contact surfaces.

In the embodiment of the 45 is the sidewall 18 designed so that they are the two edges of the reinforcing element 66 wraps around and with the thighs 12 and 16 parallel to the side wall 18 forms running joining surfaces. At the joining surface between the side wall 18 and the inner thigh 16 has the side wall 18 notches 122 on, in the tabs 124 of the inner thigh 16 intervention.

As a result, the adhesive bond of the two parts is given a higher strength. Along the joining surface between the side wall 18 and the outer thigh 12 is a welding aid in both parts 108 embedded in its shape and function that of the embodiment of 34 equivalent.

In the embodiment of the 46 sits the side wall 18 with an edge on the inner thigh 16 and forms one with him to the side wall 18 vertical joining surface. In the area of the outer thigh 12 encloses the side wall 18 the edge of the reinforcing element 66 and forms with the outer thigh 12 one parallel to the side wall 18 running joining surface.

Along the joining surfaces between the side wall 18 and thighs 12 and 16 are, as in the embodiment of 45 , Auxiliary welding elements 108 embedded.

In the reinforcing element 66 are along its contact surface with the sidewall 18 two band-shaped welding auxiliary elements 116 embedded. These melt when heating the spacer profile and ensure a cohesive connection between the side wall 18 and the reinforcing element 66 , The reinforcing element 66 is additionally by a projection 76 of the inner thigh 16 fixed.

The embodiment of 47 represents a multi-part hollow profile, wherein the legs 12 and 16 and the side walls 18 each separate components of the spacer profile form (see. 47a ). The side wall 18 sits with a brim on a ledge 104 of the inner thigh 16 on and lies with a part of its inner surface at a perpendicular to the projection 104 oriented jetty 126 of the inner thigh 16 at. The outer thigh 12 lies with its edge on the inner surface of the side wall 18 This compound is thereby given stability, that at the edge of the outer leg 12 arranged cones 128 in holes 130 the outer wall 18 intervention.

A variant of this embodiment is in the 47b shown, with only half of the outer leg 12 and a short section of a side wall 18 are shown. Here are the cones 128 on a separate intermediate part 132 arranged, which with the outer leg 12 along a parallel to the side wall 18 extending joining surface is connected. Along this joint surface is a welding auxiliary element 108 in the intermediate part 132 and the outer thigh 12 embedded, as for example in connection with the 45 and 46 has been described.

In the embodiment of the 48 forms the sidewall 18 also a separate element, which runs along its edges on the thighs 12 and 16 is present, and is slightly indented in this. The side wall 18 is relatively thick and includes embedded, longitudinally extending metal fibers 58 as induction heating elements. Instead of metal fibers and carbon fibers, metal wires, carbon wires or metallized synthetic fibers can be used, as in connection with the 14 to 17 has been described.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been 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

• DE 19805348 A1 [0006]
• DE 19807454 A1 [0006]
• DE 19961902 A1 [0010]

Claims (28)

Polygonal spacer frame with three or more corner areas for insulating glass panes or the like, made of a manufactured on the basis of an elastically-plastically deformable plastic material spacer profile means - placing a portion of the spacer profile in a heating device; - Heating the portion of the spacer profile or parts thereof to a predetermined temperature near the melting point of the material of the profile or the parts thereof; Bending the spacer profile in the region of the section to form a corner region of the frame; and - cooling the section. Spacer frame according to claim 1, characterized in that the heating is carried out by means of an induction or resistance heating device, wherein the profile is arranged together with an inductive or resistance heatable heating element in the heating device, and that the portion or its parts by means of Heating element is heated to the predetermined temperature. Spacer frame according to claim 1 or 2, characterized in that after the end of the heating of the heating element, the corner area is fixed in position, forcedly cooled. Spacer frame according to one of claims 1 to 3, characterized in that the heating element is inserted into the spacer profile in the section to be formed to the corner region. Spacer frame according to one of claims 1 to 3, characterized in that the heating element is embedded in the material of the spacer profile. Spacer frame according to one of claims 1 to 3, characterized in that the heating element with the spacer during the step of heating in heat-conducting contact is maintained. Spacer frame according to claim 6, characterized in that the heating element is removed after completion of the heating of the formed corner region. Spacer frame according to claim 6, characterized in that the heating element remains even after completion of the heating at the corner region formed. Spacer frame according to one of the preceding claims, characterized in that the heating element is designed as an induction heating element. Spacer frame according to one of claims 1 to 8, characterized in that the heating element is designed as a resistance heating element. Spacer frame according to claim 9 or 10, characterized in that the induction or Widerstandsheizelement using metal foils, metal profiles, metal fibers, carbon fibers, carbon powder, metal powder, carbon wires, metal wires and / or metallized synthetic fibers and / or conductive plastic films is made. Spacer frame according to one of the preceding claims, characterized in that the spacer profile is designed as a multi-part profile. Spacer frame according to claim 12, characterized in that the spacer profile recesses and / or recesses, in which plastic material of the profile can be displaced during bending. Spacer frame according to one of the preceding claims, characterized in that the heating element comprises recesses or recesses, in which plastic material of the profile can be displaced during bending. Spacer frame according to one of the preceding claims, characterized in that, together with the spacer profile and the heating element, a welding auxiliary element of a material having a softening temperature is arranged in the heating device, which lies below the softening temperature of the plastic material of the profile. Spacer frame according to claim 15, characterized in that the heating element is designed as a welding auxiliary element. Spacer profile for use in the manufacture of a spacer frame according to any one of claims 1 to 16, characterized in that the profile comprises a heating element which cooperates with the heating device to heat the profile or parts thereof to the predetermined temperature. Spacer profile according to claim 17, characterized in that the heating element a is inductive or resistance-heated heating element. Spacer profile according to claim 17 or 18, characterized in that the heating element is detachably connectable to the profile. Spacer profile according to claim 17 or 18, characterized in that the heating element is embedded in the plastic material of the profile. Spacer profile according to one of Claims 18 to 20, characterized in that the induction or resistance heating element is produced using metal foils, metal profiles, metal fibers, carbon fibers, carbon powders, metal powders, carbon wires, metal wires and / or metallised synthetic fibers and / or conductive plastic foils. Spacer profile according to one of claims 17 to 21, characterized in that the profile is a multi-part profile. Spacer profile according to claim 22, characterized in that the spacer profile recesses and / or recesses, in which plastic material of the profile can be displaced during bending. Spacer profile according to one of claims 17 to 23, characterized in that the heating element comprises recesses or recesses, in which plastic material of the profile can be displaced during bending. Spacer profile according to one of claims 17 to 24, characterized in that, together with the spacer profile and the heating element, a welding auxiliary element of a material having a softening temperature is arranged in the heating device, which lies below the softening temperature of the plastic material of the profile. Spacer profile according to claim 25, characterized in that the heating element is designed as a welding auxiliary element. Spacer profile according to one of claims 17 to 26, characterized in that the profile is designed as a hollow chamber profile with at least one longitudinally continuous hollow chamber. An insulating glass pane, facade element or the like, comprising a spacer frame according to one of claims 1 to 16.

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