DE102006007994A1 - Frame unit, where plastic profile frame, which peripherally surrounds element, has reinforcing components to strengthen element and receiving portion receives peripheral edge element portion - Google Patents

Abstract

The unit has a planar load-bearing element (2) with glass panes (3,4). A plastic profile frame (6), which peripherally surrounds the element, has reinforcing components to strengthen the element. A receiving portion (9) receives a peripheral edge portion of the element. An adhesive joint (17) is formed in the receiving portion to receive an adhesive bead (16) for the element bonded connection to the profile frame. The joint is bounded by one bounding wall (18) of the receiving portion on one hand and by the element on other hand. The bounding wall is formed from fiber-reinforced plastic. An independent claim is also included for the profile components of the fiber-reinforced plastic profile frame with a load-bearing element.

Description

The The invention relates to a frame assembly according to the preamble of Claim 1 and a frame profile for this.

A generic frame assembly with frame profiles is known from the DE 20 2005 001 073 U1 , There reinforcing components in the form of additional partitions in the profile frame building hollow chamber frame profiles are used to reinforce the profile frame. This should make it possible to replace metallic reinforcing profiles, which are also known as reinforcing components.

by customer be strengthened Such, bonded glazing insulating profile frame with colored Visibility pages in demand. Such profile frames have, since they are not are more white, one more Radiation absorption than the conventional white profile frame result. In a typical annual cycle, such a Frame assembly z. B. when using as a window frame passes, occur in the colored profile frame high temperature differences between the annual minimum and the Year maximum temperature on. The high temperature differences lead to the risk of frame distortion, so that a reinforcement of the frame is essential. The reinforcement by additional partitions has proved to be the solution to this Problems not suitable, because through the intermediate walls in particular undesirable additional Thermal bridges in the Profile frames arise what the heat transfer coefficient undesirable by the profile frame elevated. One simultaneous problem of the initially mentioned, generic frame assembly is the high adhesive requirement for the production of a cohesive connection of the profile frame with the insulating glazing.

It It is therefore an object of the present invention to provide a frame assembly of the type mentioned in such a way that on additional Reinforcement components can be dispensed with, while simultaneously the adhesive requirement for cohesive connection of the surface support element with the profile frame is reduced compared to the prior art.

These The object is achieved by a frame assembly with the in the characterizing part of the claim 1 specified characteristics.

According to the invention was realized that a fiber reinforcement / fiber stiffening at least the bounding wall bounding the glue line, the simplicity Half of the entire boundary wall frame profile, both the Armierungsproblem eliminated, as well as the used Adhesive quantity reduced. It has contrary to some prejudices pointed out in the professional world that it is very possible fiber reinforced / faserversteifte To provide plastic materials that are dyed can. The fiber reinforcement / fiber stiffening leads to an increase the frame stability, so on extra Reinforcement components can be dispensed with. Through the fiber reinforcement / fiber stiffening also results in an approximation the thermal expansion coefficient the boundary wall delimiting the glue joint on the thermal expansion coefficient of the surface carrying element. This allows the use of an adhesive joint compared to the state of Technique of lesser strength, because only small differences in thermal expansion over the intermediate adhesive bead must be compensated. This especially applies to colored profile frames with high Radiation absorption and correspondingly high temperature differences in the annual cycle. Preferably, an adhesive is used, whose Stretching the compensation of differences between the thermal expansion coefficient of the glue line bounding boundary wall and the coefficient of thermal expansion of the surface support element via a preferably low maximum adhesive strength allows. In principle, it is sufficient if only the boundary wall, the Adhesive joint limited, or the frame profile, which this boundary wall has, fiber reinforced / fiber reinforced is. Alternatively, the entire profile frame of fiber reinforced / fiber reinforced Plastic exist. The glue joint can be from a lateral boundary wall be limited to the receiving portion, ie in a rollover portion of the Profile frame present, or from the lower boundary wall of Be limited recording, so in a Falzgrundbereich of the receiving section.

A maximum strength the adhesive joint according to claim 2 has to compensate thermally induced Tolerances proved sufficient and allows one particularly economical adhesive application.

A Reinforcement according to claim 3 is particularly suitable for use in extruded Proven frame profiles.

materials for the Profile frame according to claim 4 are particularly well suited for fiber reinforcement / fiber stiffening.

A material according to claim 5 ensures a good surface quality, which favors a subsequent coloring of the profile frame. A K-value between 50 and 60 allows an optimal Embedding the fibers of the fiber-reinforced / fiber-reinforced plastic, which in particular facilitates a Eckverschweißung the profile frame.

One Glass fiber content according to claim 6 allows a good weldability corresponding frame profiles in particular for the production of Eckverschweißungen a square, especially in a rectangular profile frame. In particular, in Eckverschweißungen of profile frame with such glass fiber shares sufficient Eckfestigkeiten according to EN 12th 608 achievable. Also the required stiffness of the profile frame building up frame profile is achieved.

Fiber lengths after Claim 7 offer a good compromise between good weldability the frame profiles, for which the fiber lengths should be as short as possible, and stability the frame profiles, what the fiber lengths should be as long as possible.

fibers allow according to claim 8 a good weldability from having a corresponding fiber reinforcement / fiber reinforcement Frame profiles even at higher Fibers as 15 wt .-%. In particular, organic thermoplastic Synthetic fibers are used. These fibers are due to the Orientation of macromolecules significantly higher Strength properties, such as components that by Extrusion are produced. As fibers are in particular thermoplastic Plastics with a softening temperature in question, which is larger as 85 ° C.

A Another object of the invention is to provide a frame profile for construction a profile frame for a frame assembly according to the invention to accomplish.

These The object is achieved by a frame profile with the features specified in claim 9.

The Advantages of this frame profile correspond to those described above have already been explained in connection with the frame assembly according to the invention.

A Coating according to claim 10 reduces the requirements of the material the uncoated frame profile, what the impact resistance and optionally also the surface quality for the following coloring As. Material examples for the coating are PBT, ASA and SB.

One embodiment The invention will be explained in more detail with reference to the drawing.

The single figure shows a section through a broken illustrated Frame assembly with a plastic profile frame in cross section, with a Tensile element glued in the form of insulating glazing.

Shown in the figure is a section through a broken part of a window sash 1 , This has as a surface support element an insulating glazing 2 with two connected glass panes 3 . 4 on. The connection of the glass panes 3 . 4 takes place in the edge region of the insulating glazing shown in the figure 2 via a connection profile element 5 ,

The front side areas of the insulating glazing 2 be from a circumferential profile frame 6 surrounded by plastic, which is only partially shown in the section of the figure. A main profile element 7 and also referred to as a glass strip additional profile element 8th of the profile frame 6 essentially bound U-shaped a receiving section 9 for the front side area of the insulating glazing 2 , The U-shaped receiving section 9 of the profile frame 6 is also called profile fold. Those sections of the profile frame 6 , from the Falzgrundbereich on the insulating glazing 2 survive, are also called wing flashover sections of the profile frame 6 designated. The profile elements designed as hollow-chamber frame profiles 7 . 8th are made of fiber reinforced / fiber reinforced plastic by extrusion. This fiber reinforcement / fiber reinforcement provides the exclusive reinforcement of the profile frame 6 dar. The profile frame 6 thus has no additional reinforcement components, z. B. in the form of metallic reinforcing profiles, on. In the illustrated embodiment, the profile elements 7 . 8th Made of glass fiber reinforced, high impact PVC. This PVC has a K value between 50 and 60 which describes its flow properties, in particular its melt viscosity. This K value can be converted into the intrinsic viscosity of the PVC by the following relationship: [η] = 2.303 × (75k 2 + k) with K value = 1000 k

The profile elements 7 . 8th have a glass fiber content of at most 25 wt .-%, preferably at most 20 wt .-%, more preferably at most 15 wt .-%, with a length of the individual glass fibers between 1 and 3 mm.

The visible sides of the profile elements 7 . 8th have sprayed coatings 10 made of a fiber-free, highly impact-resistant plastic material. The coatings 10 are in the present embodiment of PBT (polybutylene terephthalate). Alternatively, the coatings 10 also from ASA (acrylonitrile-styrene-acrylic ester) or SB (styrene-butadiene).

At the additional profile element 8th are two mutually parallel elastic sealing lips 11 . 12 extruded, whose free ends on the wall facing the front side region of the inner glass pane 4 issue. The sealing lips 11 . 12 opposite lies in the pre-assembled state of the window sash 1 weather-side wall of the outer glass pane 3 a sealing profile 13 over mutually parallel and spaced support portions. Adjacent of these three support sections define a total of two sealing cavities between them. Over a double tongue and groove connection 14 is the sealing profile 13 positively in a latching section 15 of the main profile element 7 clipped. The sealing profile 13 serves in particular to the main profile element 7 Impact rain against the insulating glazing 2 seal.

The insulating glazing becomes static 2 over in the recording room 9 arranged and not shown in the figure block elements worn. In particular, for receiving dynamic loads, such. As wind, rain or snow loads, and to absorb thermal changes in length is the insulating glazing 2 with the profile frame 6 bonded. For this lies an adhesive bead 16 for cohesive connection of the insulating glazing 2 with the profile frame 6 in a glue joint 17 , The latter is in the figure below the sealing profile 13 arranged and is bounded on the one hand by a left in the figure boundary wall 18 the receiving section 9 and on the other hand from the weather-side wall of the glass pane 3 the insulating glazing 2 , Like the entire main profile element 7 is also the boundary wall 18 made of fiber-reinforced / fiber-reinforced plastic.

The glue joint 17 has between the boundary wall 18 of the profile frame 6 and the glass pane 3 the insulating glazing 2 a maximum thickness of 5 mm. Even lower maximum strengths, z. B. a maximum thickness of 3 mm or even only 2 mm are possible.

When optimally adjusting the coefficients of thermal expansion of the components that the glue joint 17 limit, and the stretching behavior of the adhesive is even an even lower maximum strength of the adhesive joint possible.

In the figure, the thickness S is the glue joint 17 shown exaggeratedly big. In fact, the glue line is 17 only about one-fifth as strong as the figure shows. This reduction in the thickness S of the glue joint 17 is the result of the relatively small difference between the thermal expansion coefficients of the material of the boundary wall 18 on the one hand and the glass pane 3 on the other hand. This difference is approximately one fifth of the difference between the coefficients of thermal expansion of an unreinforced PVC material and the glass of the glass sheet 3 ,

The glue joint 17 may also be elsewhere in the recording section 9 be accommodated, z. B. between a lower boundary wall in the figure 19 and the insulating glazing 2 , For the strength of such an alternative adhesive joint, what applies above to the strength of the adhesive joint 17 was executed.

Due to the reduced thickness S of the glue joint 17 results in a correspondingly reduced adhesive requirement for cohesive connection of the profile frame 6 with the insulating glazing 2 ,

Alternative materials for the fiber reinforced / fiber reinforced profile frame 6 are ABS (acrylonitrile / butadiene / styrene), ASA (acrylonitrile / styrene / acrylic ester) and SB (styrene / butadiene). These copolymers are well suited for fiber reinforcement / fiber stiffening and for adjusting the thermal expansion coefficient of the profile frame 6 on the coefficients of thermal expansion of the glass panes of an insulating glazing.

The fiber reinforcement / fiber stiffening of the fiber reinforced / fiber reinforced components of the profile frame 6 , Thus, the reinforcing components of this, can be done as an alternative to glass fibers by organic fibers polymer-based, in particular PAN (Prolyacrylonitrile).

With Such fibers also have a higher fiber content as 15 or 20 wt .-% possible. Despite this higher Fiber content remains a good weldability of the material obtained.

Claims (10)

Frame assembly ( 1 ) - with at least one glass pane ( 3 . 4 ) comprehensive surface carrying element ( 2 ), - with a the surface carrying element ( 2 ) perimetrically encircling plastic profile frame ( 6 ), which has reinforcing components for reinforcement, with a receiving section ( 9 ) for a peripheral edge portion of the surface carrying member ( 2 ), wherein - in the receiving section ( 9 ) at least one glue joint ( 17 ) for receiving an adhesive bead ( 16 ) for the cohesive connection of the surface support element ( 2 ) with the profile frame ( 6 ), - the glue joint ( 17 ) is bounded by at least one boundary wall ( 18 ) of the receiving section ( 9 ) on the one hand and from the surface carrying element ( 2 ) on the other hand, characterized in that - the at least one adhesive joint ( 17 ) delimiting boundary wall ( 18 ) is formed of fiber-reinforced / fiber-reinforced plastic, - where profile components ( 7 . 8th ) of the profile frame ( 6 ) made of fiber-reinforced / fiber-reinforced plastic, the exclusive reinforcing components of the profile frame ( 6 ). Frame assembly according to claim 1, characterized by an adhesive joint ( 17 ) with one between the surface carrying element ( 2 ) and the profile frame ( 6 ) maximum thickness of 5 mm, preferably with a maximum thickness of 3 mm, more preferably with a maximum thickness of 2 mm. Frame assembly according to claim 1 or 2, characterized characterized in that the fiber reinforcement / fiber reinforcement of the Armierungskomponenten done by glass fibers. Frame assembly according to one of claims 1 to 3, characterized by a profile frame ( 6 ) on one of the following materials: - PVC, in particular high impact strength; - ABS - ASA - SB. Frame assembly according to one of claims 1 to 4, characterized by a profile frame ( 6 ) of PVC having a K value, concerning the melt viscosity, between 50 and 100, in particular between 50 and 60. Frame assembly according to one of claims 3 to 5, characterized by a profile frame ( 6 ) having a glass fiber content not higher than 25% by weight, preferably not higher than 20% by weight, more preferably not higher than 15% by weight. Frame assembly according to one of claims 1 to 6, characterized by a fiber length of at most 5 mm, preferably between 1 and 3 mm. Frame assembly according to one of claims 1 to 7, characterized in that the fiber reinforcement / fiber stiffening of Reinforcing components by polymer-based organic fibers, in particular through PAN. Frame profile ( 7 . 8th ) made of fiber-reinforced / fiber-reinforced plastic for the construction of a profile frame ( 6 ) for a framed surface support element ( 2 ) according to one of claims 1 to 8. Frame profile according to claim 9, characterized in that the frame profile ( 7 . 8th ) a coating ( 10 ) Made of a fiber-free, high-impact plastic material.