CZ2018747A3 - Composite element for wood-glass facade systems - Google Patents

Abstract

The subject of the invention is a composite element for wood-glass facade systems. The glass pane (1) is glued to the wooden frame (2), which has an L-shaped half-groove (13) milled instead of the inner front edge at the junction of the inner and front sides of the frame (2) so that the half-groove (13) has a bottom surface (14). ) parallel to the front side of the frame (2) and a side wall (11) parallel to the inner side of the frame (2). The rear edge part of the glass pane (1) is inserted into the half-groove (13) and glued to its lower surface (14) by a layer (6) of glue. In the part of the frame (2) outside the half-groove (13) at its outer side, holes (9) are placed for attachment to the existing building structure.

Description

Composite element for wood-glass facade systems

Field of technology

The invention relates to the composition, construction and production of a composite element for wood-glass facade systems of buildings.

Prior art

Facade systems consist of elements that have a wide range of materials used and application or assembly technologies. Even in cases where glass facade systems are mounted on the underlying wooden structures and the system mainly looks like a glass-wooden structure, glass panes of single glass, double glazing or triple glazing are placed on a specially designed frame, which is metal, which does not matter aesthetically , because in normal use it is placed behind the glass panel and is quite unnoticeable. Iron metal frames are used, which are not resistant to corrosion and must be treated over time with repetitive coatings. Stainless steel is more advantageous in this respect. The disadvantage of metal profiles is their high weight and significant heat loss. Therefore, the more preferred material used is aluminum alloys, which are not subject to corrosion and are more than half lighter than steel. The negative common denominator of metal frames is energy-intensive production and, in the case of aluminum alloys and stainless steel, the higher price of the material used. During the process of aluminum production from bauxite, a strongly alkaline toxic red sludge with an increased content of radioactive substances is formed, which is very difficult to remove. In the past, toxic sludge was deposited in hazardous waste landfills, nowadays it mostly ends up in so-called sludge ponds.

In the case of these façade systems, the assembly procedure is such that the frame is first pre-assembled and fastened to the building wall. Only then is the glass pane complicatedly inserted into the existing structure, and in these cases it is placed loosely, so it must be subsequently fixed with a strip with a flexible base on four sides.

The essence of the invention

The above-mentioned drawbacks are eliminated by the composite element for wood-glass façade systems according to the invention using a wooden frame or a plywood frame instead of a metal one, which serves to securely attach the glass pane to the building façade. Wooden frames have significantly lower energy requirements for production than metal frames, they are significantly lighter than any metal and at the end of their life they do not burden the environment by ecological disposal. However, wood has completely different behavior and properties compared to metallic material, so it was necessary to solve the related new problems that occur with these glass-wood composite elements. It was therefore necessary to ensure sufficient ventilation, the simplest possible assembly and production, to ensure a safe connection of individual parts meeting the standards, sufficient flexibility of this connection and thus solve problems with different thermal expansion of materials. These objects are achieved by a method of manufacturing a composite element for wood-glass facade systems and further by a composite element produced in this way.

The present invention relates to a composite element for wood-glass façade systems comprising a glass pane attached to a shop, wherein the frame has inner, outer, front and rear sides and its inner circumference has smaller dimensions than a glass pane whose shape it replicates. it consists of strips of plywood and has a milled L-shaped half-groove instead of an inner front edge at the junction of the inner and front sides of the frame so that the half-groove has a bottom surface parallel to the front of the frame and a side wall parallel to the inside of the frame; on its lower surface with a layer of construction glue for wood and glass

- 1 CZ 2018 - 747 A3 the rear edge part of the glass pane is glued, while in the strips of wooden plywood outside the half-groove at the outer side of the frame there are holes for attachment to the existing building structure.

Plywood strips with a milled half-groove are individually glued to the glass pane around the perimeter so that these strips adhere to each other at the corners, but are not necessarily connected to each other by any fixed connection, the frame shape is held together by a glued joint between plywood wood strip. and a glass pane. Thus, it is not a frame as in the picture, in which the glass pane would be inserted or thanks to which, for example, individual layers of double glazing or triple glazing would hold the glass pane together, but individual parts of the frame - plywood strips are gradually added to the glass pane, attached to this glass board by gluing, the main function of this frame is to attach the glass board to the existing structure of the building. The term profile is interchangeable with the term k, however, because it will be mainly the boundary of the four sides of a rectangular glass pane - the resulting shape will resemble a wooden frame, so this term was chosen. The resulting composite element looks like a glass sheet glued in a frame, but essentially the glass sheet is only edged with these strips. By glass pane is meant in particular simple glass, double glazing or triple glazing. The width of the plywood strips and the thickness of the frame are calculated according to construction calculations, mainly depending on the materials used, weight and dimensions of the glass pane, etc. The half-groove forms a safety device against sliding or slipping of the glass pane. The side walls of the half-groove form a circumferential shape of such dimensions that the glass pane is delimited by them, and in order for the glass pane to fit into this groove, these dimensions need only be slightly larger than the circumference of the glass pane. On the contrary, the lower surface of the half-groove must support the glass pane from behind so that the glass pane does not fall through the frame. The adhesive used is an adhesive usable in construction resistant to weather conditions, sunlight and static stress, suitable for creating a strong and permanent connection between glass and wood. Holes for attachment to the existing structure are used to insert the fastening elements, most preferably screws or bolts ensuring cohesion on the base material of the existing house structure, for example into the wall, columns or beams in the existing building structure. The composite element created by combining glass and a wooden frame allows easy assembly and eventual disassembly on the wall of the building.

In contrast to the assembly used in the prior art, according to the invention, a fastening wooden frame is fixed to the glass pane before assembly, and it, together with the glass pane, is further fastened to the building structure by means of several screws. Installation is therefore significantly easier.

The wooden frame is preferably made of beech or birch plywood. In certain applications, wood plywood can be replaced directly by a wood frame, the use of wood as a material for the frame is essential.

In a preferred embodiment, the thickness of the adhesive layer between the rear of the glass sheet and the bottom surface of the half-groove is further defined on this surface along the inside of the frame by an inserted spacer strip. The spacer strip is preferably elastic. The elastic spacer strip together with the adhesive layer ensure a firm and at the same time limited elastic connection. The required thickness of the adhesive layer depends in particular on the properties of the adhesive, the materials used, the weight and the size of the glass sheet. Therefore, it is first calculated and then, according to this calculation, the thickness of the elastic spacer strip is determined, which defines the thickness of the adhesive layer. This elastic spacer strip is best placed along the entire inner circumference of the frame on the bottom surface of the half-groove so that when the adhesive is applied and the glass sheet is laid, it forms a barrier against the adhesive leaking towards the inner circumference of the frame.

The invention solves a strong, non-detachable connection of glass to a wooden frame, which sufficiently resists weather conditions, is somewhat flexible, so that it reliably compensates for different thermal expansion of materials at the wood-glass joint and is resistant to vibrations and deflections under wind load.

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In a preferred embodiment, the elastic spacer strip is made of polyurethane foam. It is possible to use commonly known adhesive tapes made of open polyurethane foam provided on both sides with, for example, a PSA adhesive based on rubber, from the English Pressure Sensitive Adhesive.

In a preferred embodiment, a layer of adhesive is also applied between the side wall of the half-groove and the glass sheet, the thickness of which layer can be defined by the diameter of the removable spacer bars used in the manufacture.

In a preferred embodiment, the frame is profiled on its outer side so as to form a ventilation channel by maintaining a certain air gap and behind this distance fits into the outer side of the profiled frame of an adjacent composite element, for example into interlocking teeth, the frame having a frame in the profiled part. holes for attachment to the existing structure of the building. Ie. that on the outside of the plywood strips there is a specially shaped edge resembling rounded teeth in which holes are drilled for attachment to the wall of the building.

The adhesive used is preferably a silicone-based adhesive which is cured by air humidity.

Another object of the invention is a wood-glass façade system comprising the above-described composite elements such that the composite elements fit into each other with their outer sides and are placed side by side in a spacing gap forming a ventilation channel.

Another object of the invention is a method of manufacturing the above-described composite element for wood-glass facade systems comprising a frame and a glass pane, the essence of this method of production being that first four plywood strips of width and thickness corresponding to the required frame dimensions, and length according to the dimensions of the glass pane, remove the edge at the junction of the inner and front sides of the plywood strips by milling an L-shaped half-groove so that the half-groove has a bottom surface parallel to the front of the frame and a side wall parallel to the inside of the frame; it is profiled by machining so that, by maintaining a certain air gap forming the ventilation channel, it fits in shape to the outside of the profiled plywood strip of an adjacent composite element, for example in the form of interlocking teeth, and holes are formed in this profiled part for attachment to the existing building structure. strips of plywood with its front side turned ou up on a horizontal surface in the shape of a regular quadrangular frame so that the inner sides of these strips form the inner circumference of the frame and the front sides of these strips are identical to the front of the frame, an elastic spacer strip is glued to the bottom surface along the inner side of the frame and the rest of the bottom surface of the half-groove is applied construction glue for glass and wood to fill the space between the glass pane and the frame further defined by the elastic spacer strip, the glass pane is placed on the elastic spacer strip with its rear edge part of the glass pane, and the composite element is left still for the time required for the adhesive to cure. The amount of construction adhesive for glass and wood required to fill the space between the glass pane and the frame further defined by the elastic spacer strip can be calculated in advance by standard methods.

In a preferred embodiment, at least two spacer bars are placed in the applied adhesive at a sufficient distance to the side wall of the half-groove of each plywood strip after the adhesive has been applied, the amount of adhesive, preferably pre-calculated, increased by the volume to fill additional space between the glass pane the wall of the half-groove defined by the spacer bars and only then a glass sheet is placed on the elastic spacer strip and then the spacer bars are removed and the composite element is left to stand for the time required for the adhesive to cure.

The advantage of this method of production is that the adhesive does not flow along the inside of the wooden frame, as the elastic spacer strip prevents it from flowing out in this direction. The milled half-groove further determines the direction of glue extrusion along the side wall of the half-groove, and accurate calculation of the amount of glue ensures the optimal amount of glue so that this glue does not flow onto the front

-3 GB 2018 - 747 A3 side of the frame or on the front of the glass pane. This creates a tub for the adhesive that does not leak and is cured at rest for a suitable time.

Explanation of drawings

The essence of the invention is further elucidated on the basis of examples of its embodiment, which are described with the aid of the accompanying drawings, where:

a schematic part of a wood-glass facade system is shown with four composite elements according to the invention with a marked element, which is further presented in detail in Fig. No. 2 shows a detail of one composite element according to the invention, two adjacent frames of two adjacent composite elements with a zigzag ventilation channel in the form of an air gap between the profiled rounded teeth at the outer edges of the wooden frames and with holes for mounting in the existing structure shows a section of the wooden part of the frame of Fig. 3 with a milled L-shaped half-groove showing a detailed section of a composite element according to the invention installed in the existing the structure shows a projection into the glued joint - from the view of the front part of the glass pane, a part of a strip of wooden plywood with an elastic spacer strip and with spacer bars is shown before placing and gluing the glass pane

Examples of embodiments of the invention

The invention will be further elucidated on the basis of exemplary embodiments with reference to the respective drawings. An exemplary embodiment is an assembly of several composite elements for wall mounting of an existing building structure, a part of such a wood-glass façade system with an indication of four composite elements is shown in Fig. 1.

In a first exemplary embodiment, the composite element included a glass sheet 1 embedded and adhered with a silicone-based adhesive to the L-shaped half-groove 13 of the wooden frame 2, as shown in Figures 2 and 5. This exemplary embodiment was made in alternatives where the glass sheet 1 was made of glass. , double glazing or triple glazing, which with its rear edge part 15 was inserted into the wooden frame 2 and glued with a layer of glue at the bottom surface 14 of the half-groove of this wooden frame 2. The half-groove 13 was made by milling the inner front edge at the junction of the inner and front sides of the frame into recesses; letter "L", see Fig. 4. The half-groove 13 had a bottom surface 14 parallel to the front of the wooden frame 2 and a side wall 11 parallel to the inner side of the frame 2. The inner circumference of the frame copied the shape and had slightly reduced dimensions, e.g. 14 mm than glass pane L

The wooden frame 2 was profiled on its outer side in the form of profiled rounded teeth 17 at regular intervals, and in each such tooth 17 a hole 9 was formed for a screw 16 / screw to attach to the existing structure, i.e. to the base material on the building wall. Furthermore, alternatives have also been created with two and three such holes 9 in each tooth 17. see Fig. 3, through which the wooden frame 2 is firmly attached to the base material on the wall of the building by means of screws 16 or screws. This base material is, for example, a grate made of glued wooden beams of the KVH type - from the German Konstruktionsvollholz, ie a structural wooden prism, or BSH

-4 CZ 2018 - 747 A3 from German Brettschichtholz, ie glued laminated timber. The wooden frame 2 of the composite element was in one embodiment made of beech and in the other embodiment of birch plywood. In the exemplary embodiment, the wooden frame 2 is attached to the base grate 8 of the existing structure of wooden beams of the KVH or BSH type by building screws 16 meeting the required calculated strength.

In one exemplary embodiment, the double glazed glass pane 1 is attached to the wooden frame 2 by means of a layer of silicone-based adhesive 6 by inserting an elastic spacer strip 5 of polyurethane material along the inside of the wooden frame 14 along the inside of the wooden frame. , which occupies about 1/10 of the width of this bottom surface 14 of the half-groove, and a silicone-based adhesive with a layer thickness of 6, which corresponds to the construction calculation and depends on the size and weight of the glass sheet 1, is applied to the remaining part of the bottom surface 14 of the half-groove. the calculated thickness of the adhesive layer 6 also had the spacer elastic strip 5 slightly compressed after the placement of the glass sheet 1, which defined the desired thickness of the application of the adhesive layer 6. In an exemplary embodiment, the silicone-based adhesive layer 6 was solved only on the bottom surface 14 of the half-groove of the wooden frame with an elastic spacer strip 5 which was laid along the entire inner circumference of the wooden frame 2. In an alternative embodiment in Figs. silicone-based is also formed between the side of the glass pane 1 and the side wall 11 of the half-groove by means of removable spacer bars 10 which are embedded in the adhesive layer 6 at the side wall 11 of the half-groove at a sufficient distance, calculating the amount of adhesive required 11 half grooves. These spacer bars 10 from the headless nails were removed after placing the glass sheet 1 on the spacer strip in the half-groove 13 of the wooden frame 2.

In the specific case for the width 23 mm of the bottom surface 14 of the half-groove, the spacer strip 5 occupied only 3 mm of this width, so that the adhesive used, which was similar to silicone glazing sealant, was pressed on this surface to the remaining width of 20 mm. was further extruded into the gap along the side wall 11 of the half-groove and at the same time along the sides of the glass pane 1, in a defined space given by spacer bars 10 with a diameter of 3 mm and a height of 3 mm.

In another specific case for double glazing with a total glass thickness of 6 mm and a cavity between the panes of 16 mm, an amount of glue was required along the side wall 11 of the half-groove corresponding to 26 x 3 mm cross section, so that the glue flows to the edge of the glass pane 1 or the walls of the half-groove, which is shown in Fig. No. 6.

To equalize the air pressure and for ventilation, an air gap 7 was formed between the outer parts of the wooden frames of adjacent tooth-shaped composite elements 17, which created a zigzag ventilation channel around the whole wooden frame 2 and serves to vent and eliminate possible small inaccuracies in the profiled outer part of the wooden frame. 2.

Example of a method of manufacturing a composite element for wood-glass facade systems according to the invention, whose double glazed glass pane 1 has area dimensions of 2000 x 1000 mm, birch plywood wooden frame 2 has a corresponding required thickness of 20 mm measured as frame thickness 3, calculated thickness without milling and cut-outs, and the calculated corresponding thickness of the layer 6 of silicone-based adhesive is 3 mm, comprises the following steps:

1. The starting material of the wooden frame 2 is 4 pieces of birch plywood strips with a width of 50 mm and a thickness of 20 mm, which corresponds to the required thickness 3 of the frame. The length of the plywood strips is determined by the dimensions of the resulting composite element and the glass pane 1, i.e. 2 pcs with a length of 1000 mm and 2 pcs with a length of 1950 mm.

2. Using a four-sided milling machine, the material of the plywood strips is milled to a final width of 46 mm, which corresponds to the required width of 4 plywood strips for frame 2, and a half-groove 13 measuring 26 mm x 8 mm, L-shaped half-groove is further milled. 13.

-5 CZ 2018 - 747 A3

3. The milled strips of wood plywood are transferred to a CNC machining center, where the rounded teeth 17 of the outer part of the wooden frame are milled / profiled for future attachment to the substrate in the building wall and holes 9 are created for attachment to the existing structure with screws 16 or screws. .

4. The finished milled plywood strips shall be placed on a flat surface in a shape corresponding to the edges of double glazing measuring 2000 mm x 1000 mm.

5. An elastic spacer strip 5 3 mm thick with a width of 3 mm is glued to the bottom surface 14 of the L-shaped half-groove along the inside of the wooden frame and to the rest of the bottom surface 14 of the half-groove, i. between this elastic spacer strip 5 and the corner of the milled half-groove 13, i.e. the bend of the letter L, a silicone-based adhesive is applied in an amount corresponding to a cross section of 23 x 3 mm.

6. Along the side wall 11 of the half-groove, spacer bars 10 with a diameter of 3 mm, 3 are placed at each end of the plywood strip, but preferably several spacer bars 10 along the entire side wall 11 of the half-groove of each strip.

7. On the wooden frame 2 thus prepared, see Fig. 7, with an elastic spacer strip 5 and with an adhesive application on the half-groove 13, a glass pane 1 of double glazing is inserted with an accuracy of ± 0.5 mm.

8. The double-glazed glass sheet 1 presses the adhesive applied to the layer 6 of thickness given by the elastic spacer strip 5 in an "L" half-groove, i.e. 3 mm, by its own weight or by means of pressure and flows around the spacer bars 10 up to the edge of the glass sheet 1.

9. Once the adhesive has been extruded, spacer bars 10 with a diameter of 3 mm are removed from the adhesive overflow.

10. The composite element for wood-glass facade systems then remains at rest for the time given by the technical sheet of the adhesive for curing and is then erected with the surface of the glass pane perpendicular to the floor. It can only be used after the time required for the adhesive to cure has elapsed. At normal temperature and humidity, curing takes place approximately 1 mm in 1 hour, ie a layer of adhesive with a width of 23 mm will cure in about 1 day, but it is necessary to take into account the reserve.

In other words, two strips of plywood of the same length as the glass sheet 1 and two further strips of plywood of the same length as the glass sheet 1 are taken. Each strip is milled so that the flank is shaped into tooth shapes on one side and one is pre-drilled here. up to three holes 9 for attachment to the existing structure. On the side of the remaining straight side, a half-groove 13 is milled from above, the width of which is given by the calculated width of the required adhesive application plus the width of the elastic spacer strip 5 plus a width equal to the calculated thickness of the adhesive layer 6. This thickness of the adhesive layer 6 also indicates the thickness of the elastic spacer strip 5 and spacer bars 10, see Fig. 7. The half-groove 13 has an elastic spacer strip 5 glued to its lower surface and spacers 10 adjoining the side wall 11 of the half-groove are plastic thin. combs. A layer 6 of adhesive is applied to the bottom surface 14 of the half-groove in an appropriate amount to have a final cross section of 26 x 3 mm after curing. The plywood strips are placed on a flat surface so that the spacer bars 10 on the side wall 11 of the half-groove abut the glass pane L. The glass pane 1 is placed in the half-groove 13 and pushes the adhesive along the side wall 11 of the half-groove with slight additional pressure presses the plywood strips towards the sides of the glass. Immediately afterwards, the spacer bars 10 are removed so that the same gap remains between the glass pane and the side wall 11 of the half-groove. a layer of adhesive as on the bottom surface 14 of the half-groove, where it is delimited by a spacer strip 5. After a corresponding curing time, in this particular case of about 24 hours, the composite element can be built flat with the glass sheet 1 perpendicular to the floor. but it is not necessarily necessary.

-6 CZ 2018 - 747 A3

The production process is tied to the dimensions of the final product, so for other dimensions the process must be modified accordingly. Likewise, the technical data sheets of the manufacturer must be observed when using adhesives. It is to be understood that the terms silicone adhesive, silicone-based adhesive or silicone sealant are commonly used interchangeably in the art, but are in fact mostly silicone-based adhesive.

Industrial applicability

The composite element for wood-glass facade systems, which is the subject of the present invention, can be used wherever mounted facade elements on the walls of buildings using glass are envisaged.

Claims (9)

PATENT CLAIMS A composite element for wood-glass facade systems comprising a glass pane (1) attached to a frame (2), wherein the frame (2) has inner, outer, front and rear sides and its inner circumference has smaller dimensions than the glass pane (1). , the shape of which is copied, characterized in that the frame (2) is composed of strips of plywood and has a L-shaped half-groove (13) milled instead of the inner front edge at the junction of the inner and front sides of the frame (2) so that the half-groove (13) ) has a bottom surface (14) parallel to the front side of the frame (2) and a side wall (11) parallel to the inner side of the frame (2), inserted into the half-groove (13) and on its bottom surface (14) by a layer (6) adhesives for wood and glass glued the rear edge part (15) of the glass pane, while in the strips of plywood outside the half-groove (13) at the outside of the frame (2) there are holes (9) for attachment to the existing building structure. Composite element according to Claim 1, characterized in that the frame (2) is made of beech or birch plywood. Composite element according to any one of the preceding claims 1 to 2, characterized in that the thickness of the adhesive layer (6) between the rear of the glass pane (1) and the bottom surface (14) of the half-groove is further defined on this surface (14) along the inner surface. sides of the frame (2) by an inserted spacer strip (5). Composite element according to any one of the preceding claims 1 to 3, characterized in that the spacer strip (5) is preferably elastic made of polyurethane foam. Composite element according to any one of the preceding claims 1 to 4, characterized in that the adhesive layer (6) is also applied between the side wall (11) of the half-groove and the glass pane (1). Composite element according to one of the preceding claims 1 to 5, characterized in that the profiling of the frame (2) on the outside has the shape of rounded teeth (17) at regular intervals adapted to fit into the outside of the adjacent profiled frame (2). where it is in these teeth (17) that one to three holes (9) are located for attachment to the existing structure. -7 CZ 2018 - 747 A3 Wood-glass façade system made of composite elements according to any one of the preceding claims 1 to 6, characterized in that the composite elements interlock with their outer sides and are arranged next to one another in an air outlet gap (7) forming a ventilation duct. A method of manufacturing a composite element according to any one of claims 1 to 4 for wood-glazed façade systems comprising a frame (2) and a glass pane (1), characterized in that first four plywood strips with a width and thickness corresponding to the required frame dimensions and further in length according to the dimensions of the length of the sides of the glass pane (1), the edge at the junction of the inner and front side of wood plywood strips is removed by milling the L-shaped half-groove (13) so that the half-groove (13) has a bottom surface (14) parallel to the front side. frame (2) and a side wall (11) parallel to the inner side of the frame (2), the outer side of the plywood strips is profiled by machining so that by maintaining a certain air gap (17) forming a ventilation channel it fits into the outer side of the profiled strip of plywood of an adjacent composite element, and in this profiled part holes (9) are made for attachment to the existing structure of the building, strips of plywood with their front side facing up on a horizontal surface in the shape of a regular quadrangular frame (2) so that the inner sides of these strips form the inner circumference of this frame (2) and the front sides of these strips are identical with the front of the frame, into the half-groove (13) ) adheres an elastic spacer strip (5) along the inside of the frame and a construction adhesive for glass and wood is applied to the rest of the bottom surface (14) of the half-groove to fill the space between the glass pane (1) and the frame (2) further defined by the elastic spacer strip (5). ), a glass sheet (1) is placed on the elastic spacer strip (5) in the half-grooves (13) in the frame (2) and the composite element is left to rest for the time necessary for the adhesive to cure. A method of manufacturing a composite element according to claim 8, characterized in that at least two spacer bars (10) are placed in the applied adhesive at a sufficient distance to the side wall (11) of the half-groove of each plywood strip after the adhesive is applied, the amount of adhesive being increased by the volume to fill the additional space between the glass pane (1) and the side wall (11) of the half-groove defined by the spacer bars (10), and only then is the glass pane (1) placed on the elastic spacer strip (5) and subsequently the spacer bars ( 10) remove and leave the composite element at rest for the time required for the adhesive to cure.