NL1042932B1 - Facade construction, and method for manufacturing thereof - Google Patents

Abstract

Described is a facade structure (100), comprising: a base unit (10), comprising a framework (15) of uprights and beams with insulating elements (16) arranged therein and provided on both sides with an outer cladding (14) and inner cladding (18) ; an insulation support plate (35) secured to the outside of the outer cladding (14); insulation plates or packages (23) secured to the outside of the insulation support plate (35). Preferably, there are furthermore supporting ribs (32) mounted on the insulation packages (23), preferably by screws (33) which extend through the insulation packages (23) and engage on the uprights (15) of the base unit (10).

Description

FIELD OF THE INVENTION

The present invention relates in general to a building construction for building homes or other buildings. More in particular, the invention relates to the construction of the exterior facade.

BACKGROUND OF THE INVENTION

A home (or other building) has walls that can be subdivided into inner walls and outer walls. An outer wall forms the transition to the outside air, and is also indicated as a facade, sometimes even for clarity as an outer facade. "

An exterior facade must meet a number of conditions. In a traditional way of building, the outer facade is part of the load-bearing construction of the building, and must therefore have sufficient strength and bearing capacity. In addition, the exterior facade must meet requirements with regard to insulation and ventilation.

Traditionally, the idea is that insulation and ventilation must be installed in a cavity. The traditional construction of an outer facade therefore comprises two wall parts or wall bays (typically brick or concrete), spaced apart. Insulation material is then installed in the space remaining between the wall floors (the cavity). We find a similar solution at Houtskeletbouw, where insulation is placed between the load-bearing posts in a type of sandwich façade.

Such solutions will certainly offer good quality results, but have the disadvantage, among other things, that the entire construction is very heavy and cannot qualitatively achieve all aspects with regard to sustainability and circular.

Figure 1 shows schematically a horizontal cross-section of a part of a traditional outer wall 1A of a building. The top is facing outwards, the bottom is towards the inside of the building.

Reference 2 denotes a masonry inner wall sheet, Reference 3 denotes a masonry outer wall sheet, at a distance from the inner wall sheet 2. As a variant, the inner wall sheet 2 is also made of concrete.

The space 4 between the inner wall sheet 2 and the outer wall sheet 3 is referred to as a cavity. An insulating material 5 is provided in the cavity 4 for thermal insulation.

Usually the wall tops 2 and 3 have a thickness of 110 mm; thicker walls are also applied. Such walls are particularly heavy.

The cavity 4 typically has a width of 5-7 cm. This is a limitation for the application of insulation material, and in new construction people are often forced to use a solvent-containing PUR / PIR board. Such plates are not circular, and over time the insulation value decreases due to the solvent (gas out).

Figure 2 is a cross-sectional view similar to Figure 1 of an outer wall 1B, the inner wall sheet of which is made of timber frame construction. Reference 5 denotes a framework of vertical and possibly horizontal beams, which is filled with insulating material 8, which is provided with plating 6 and 7 on both sides. 6 is normally an OSB board, and 7 is normally a finishing board, for example plasterboard . The vertical beams 5 form the load-bearing structure, and have a width (vertical in the figure) of usually 170 mm. Consequently, the insulation package can have a thickness of 170 mm, and mineral wool can be used, for example.

This construction has a considerably more favorable weight than the brick / concrete construction of figure 1. However, the outer wall sheet 3 is often again a brick wall, so that the wall as a whole is still quite heavy.

Moreover, in many cases a thickness of 170 mm is insufficient for an insulation package of mineral wool. This can then be solved by using thicker beams, whereby a thicker insulation package can be applied, but this is accompanied by a higher weight and higher costs. In terms of construction, timber frame construction could therefore be made slimmer and therefore lighter, but the necessity of achieving a high insulation value means that heavier wood is required.

SUMMARY OF THE INVENTION

It is an object of the invention to provide a particularly light outer wall, which can be made very easily prefabricated, and has a high insulation value with natural insulation.

To this end, the outer wall has the features of claim 1.

The facade proposed by the invention is airtight in accordance with the applicable standards. With correct dimensioning there is airtightness between the structural bearing part and the outside air, with which this concept distinguishes itself from other types. The structural bearing part is also additionally insulated. This shell can also be fully equipped with provisions for, for example, gas, water and electricity, without adversely affecting the airtightness of the construction, as with other types of facades. By gluing most of the insulation on the “outside” of the shell, a solid building solution is created physically and the entire façade is vapor-open but still airtight. The application of the circular PE profile as a spacer for various types of façade finishing means that there is great diversity .

BRIEF DESCRIPTION OF THE DRAWINGS

These and other aspects, features and advantages of the present invention will be further elucidated by the following description of one or more exemplary embodiments with reference to the drawings, in which like reference numerals indicate identical or similar parts, and in which: figure 1 schematically shows a horizontal cross-section of a part of a traditional outer wall made of brickwork;

Figure 2 is a cross-sectional view similar to Figure 1 of an outer wall partially constructed in timber frame construction;

Figure 3 shows diagrammatically in cross-section the construction of an outer wall in timber frame construction according to the present invention.

DETAILED DESCRIPTION OF THE INVENTION

Figure 3 shows diagrammatically in cross-section the construction of an outer wall 100 in timber frame construction according to the present invention. This structure comprises three separate functional units 10, 20, 30.

The first functional unit 10 provides the structural strength of the wall, and is therefore also referred to as the base unit. The basic unit 10 comprises a framework 15 of uprights and beams with insulating elements 16 arranged therein, for example rock wool, and provided on both sides with a wooden plating 14 and 18, for example OSB plate / construction plate. The truss 15 and the insulating elements 16 arranged therein are thus, as it were, balanced between the plates 14 and 18. The truss 15 together with the plates 14 and 18 form a sturdy box, strong enough to support the wall in question. Reference 13 denotes a finishing plate, such as a plasterboard. Dotted line 17 denotes an airtight tape applied to the side of the uprights and beams 15 facing the outer plate 14, to ensure the airtightness of the outer wood layer

14.

The second unit 20 will be referred to as an insulation unit. The insulation unit 20 comprises an insulation support plate 21, for example a cement-bonded plate or a plaster fiber board. The insulating support plate 21 is secured to the outside of the outer plate 14 of the base unit 10, for example by screws. On the outside, insulation plates or insulation packages 23 are glued to the insulation support plate 21; reference numeral 22 indicates the adhesive layer. The insulation plates or insulation packages 23 are light and can be easily carried by the insulation supporting plate 21; tests have shown that tensile forces of 700 kg / m ² can easily be resisted.

The third unit 30 will be referred to as a finishing unit, and comprises a facade finish 31, for example sheet metal or trellis, of any desired appearance, appearance and material, for example wood or brick slips.

To apply the facade finish 31, (vertical and / or horizontal) support ribs 32 are attached to the insulation packages 23, preferably made from recycled Poly Ethylene. This fixing is done by screws 33, preferably stainless steel, which extend through the insulation packages 23 and engage on the uprights 15. The façade finish 31 is then placed on the supporting ribs 32, for example screwed. The supporting ribs 32 ensure that a ventilation gap 34 remains free between the facade finish 40 and the insulation 27.

The main insulation 23 is now located outside the supporting structure 10. A mineral wool (rock wool) with a large thickness can be used, as a result of which a high insulation value is already achieved without having to use PUR / PIR material and / or other gaseous / opioid insulating materials. Furthermore, it is important that this insulation is placed outside the airtight shell formed by the plates 14 (and 21) and the airtight seal 17.

Within the airtight shell, in the structural wall 10, a secondary insulation 16 is provided, which can be of the same material as the main insulation 23. This insulation can be considerably thinner than in the known timber frame construction (figure 2), so that also the uprights 15 may be narrower; a width of 120 mm is sufficient for strength reasons.

The main insulation 23 can then, for example, have a thickness of 230 mm. The condensation line will be reliably far beyond the airtight shell. An additional advantage: less structural construction and yet a high insulation value which is approximately 1.5 factor better than the current new construction decree. In addition, the "light building construction" makes it possible to build new homes on existing foundations. The big advantage is that homeowners have fewer demolition costs and that construction waste can be greatly reduced.

The proposed construction thus offers the advantages of high strength, high insulation and low weight in combination. Due to the low weight, in the case of existing buildings, construction on existing foundations will be possible, resulting in a considerable saving on demolition costs and less (demolition) waste being produced. By using existing foundations, it is easier to get construction plans accepted, and building is quicker.

Due to the low weight, building itself will also be easier and will require fewer heavy facilities. If applied in new construction at locations of the subsurface is not sufficiently strong and therefore needs to be driven, fewer piles will be needed.

The use of supporting ribs 32, which on the one hand serve as a mounting place for the façade finishing 31 and which on the other hand serve to define a ventilation gap, which supporting ribs 32 can be made of new wood but are preferably made of recycled material such as PE, for example recycled caps of PET bottles, it is possible to achieve circular objectives. The entire wall construction can be called circular in this way.

It will be clear to a person skilled in the art that the invention is not limited to the exemplary embodiments discussed above, but that various variants and modifications are possible within the scope of the invention as defined in the appended claims.

Any reference numbers used in a claim should not be construed as limiting the scope of that claim.

Claims (16)

CONCLUSIONS A method of manufacturing a facade structure (100) comprising the steps of: providing a base unit (10) comprising a framework (15) of uprights and beams with insulating elements (16) arranged therein and provided on either side with an outer cladding (14) and inner cladding (18); attaching an insulating support plate (35) to the outside of the outer cladding (14); and securing insulation plates or insulation packages (23) against the outside of the insulation support plate (35). Method according to claim 1, wherein the insulation plates or insulation packages (23) are glued against the insulation support plate (35). Method according to claim 1 or 2, wherein the insulation plates or insulation packages (23) are of the same insulation material as the insulation elements (16) of the base unit (10). Method according to any of the preceding claims, wherein the insulation plates or insulation packages (23) and / or the insulation elements (16) of the base unit (10) are of mineral wool, preferably rock wool. Method according to any of the preceding claims, wherein the insulation plates or insulation packages (23) are thicker than the insulation elements (16) of the base unit (10). A method according to any of the preceding claims, further comprising the step of mounting support ribs (32) on the insulation packages (23), preferably by screws (33) extending through the insulation packages (23) and engaging the uprights (23) 15) of the basic unit (10). Method according to claim 6, further comprising the step of applying a facade finish (31), for example sheet metal or trellis, for example wood or brick slips, on the bearing ribs (32), while keeping a ventilation gap (34) free between the facade finish (34) 31) and the insulation (23). A method according to claim 2 or 3, wherein the spacer / carrier ribs (32) are made from Poly Ethylene, preferably recycled PE, most preferably recycled PET bottle caps. A facade structure (100) comprising: a base unit (10), comprising a framework (15) of uprights and beams with insulating elements (16) arranged therein and provided on both sides with an outer cladding (14) and inner cladding (18); an insulation support plate (35) secured to the outside of the outer cladding (14); insulation plates or packages (23) secured to the outside of the insulation support plate (35). The facade structure according to claim 9, wherein the insulation boards or insulation packages (23) are glued against the insulation support plate (35). A facade structure according to claim 9 or 10, wherein the insulation boards or insulation packages (23) are of the same insulation material as the insulation elements (16) of the base unit (10). Facade structure according to any of the preceding claims 9-11, wherein the insulation plates or insulation packages (23) and / or the insulation elements (16) of the basic unit (10) are of mineral wool, preferably rock wool. A facade structure according to any of the preceding claims 9-12, wherein the insulation plates or insulation packages (23) are thicker than the insulation elements (16) of the base unit (10). Facade structure according to any of the preceding claims 9-13, further comprising support ribs (32) mounted on the insulation packages (23), preferably by screws (33) which extend through the insulation packages (23) and engage on the uprights (15) of the basic unit (10). The facade structure according to claim 14, further comprising a veneer finish (31) disposed on the bearing ribs (32), e.g. sheet metal or trellis, e.g. wood or brick slips, with a ventilation slit (34) between the veneer finish (31) and the insulation (23) . A facade structure according to claim 14 or 15, wherein the spacer / bearing ribs (32) are made from Poly Ethylene, preferably recycled PE, most preferably recycled PET bottle caps. 1/3

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