NO972255L - Building kits for the construction of buildings - Google Patents

Description

The present invention relates to the use of a known form of insulation material consisting of a cement-stabilized mixture of cement and a porous, artificial sofa-based insulation material such as expanded polystyrene (EPS), which mixture goes by the trade name "Thermo-zell", or a mixture of another expanded plastic material such as polyurethane and cement.

By mixing cement and an expanded plastic material such as expanded polystyrene, it has been shown that a material is produced that avoids the low impact resistance of the polystyrene by the fact that the cement provides a more impact-resistant structure to the finished product than what is exhibited by expanded polystyrene alone, at the same time as a mixture of expanded polystyrene particles gives the mixture a significantly lighter specific weight than compact cement and adds significantly improved insulating properties to the final material.

In addition, such a mixture is difficult to ignite as it can act as a fire shield, and it has good insulating properties based on the combined insulating properties of both expanded polyethylene and cement.

However, it has been shown that such mixtures have not been used for load-bearing constructions within the construction industry due to the mixture's light and low load-bearing properties alone.

It has now surprisingly been shown that if a mixture of cement and an expanded plastic is added to other non-load-bearing or poorly load-bearing constructions, the mixture and the non-load-bearing or poorly load-bearing construction will give a significantly better load-bearing capacity than what could be expected from the sum of the load-bearing capacities of the materials and constructions combined. It thus appears that there is a form of synergistic effect regarding the load-bearing properties when the mixture of expanded plastic material and cement is added to non-load-bearing or poorly load-bearing building elements so that a load-bearing structure with properties sufficient to be able to use them as load-bearing elements in building constructions.

By using building elements constructed in this way, building sets can be designed comprising a small number of basic elements that can be used to create most forms of building construction. When using such elements, formwork elements for cement-based EPS insulation can be built, where elements become part of the finished wall construction in the building. It is previously known that pre-moulded EPS blocks can be used for this purpose in order to form a ready-made insulated wall with a concrete/cement core, but such a previously known type of wall does not utilize the above-mentioned synergistic effect between cement and EPS/polymer . In order to construct a complete wall, different blocks had to be made for long walls, corners, door and window openings etc. at the same time as the wall thickness was given and the cavities inside the block were the same. Such a form of block is often unnecessarily expensive due to the many models/items, and not least this was associated with large transport costs as the cavity in the block could not be utilized effectively.

When designing combined load-bearing and insulating elements according to the present invention, as explained above, pre-formed elements will be able to be reduced to only four element blanks that can be transported in compact form to the building site.

Design of a construction set for buildings comprising load-bearing cement-stabilized EPS elements as well as spacer elements of insulating plastic material between these load-bearing elements

can be designed as shown in the accompanying figures. where:

Fig. 1 shows a possible design of a number of connecting EPS elements that can be placed between two wall plate elements, Fig. 2 shows a composition of two wall elements that are connected together with a number of connecting EPS elements as shown in fig. 1, Fig. 3-5 show alternative designs of the connecting EPS elements that fasten the wall panels together. Fig. 6 shows a design of a joint between stacked wall elements.

The assembly of a load-bearing wall with the elements according to the invention will take place so that two wall panels 1 comprising a number of grooves 2 which in design correspond to the outer edges 3 of the connecting elements 4, are bound together by the elements 4 by placing the elements 4 in the grooves 2. The outer edges 3 of the connecting elements 4 can be designed with a round, T-shaped, conical etc. area that fits into the grooves 2 in the wall elements 1. The width and height of the elements 4 are arbitrary, but should not be made too large. The dimensions of these elements will be professional and can easily be determined for a given wall type. By placing several such elements 4 with the outer edges 3 above each other in the grooves 2, and placing wall elements 1 on each side of the connecting elements 4, a wall construction will be formed which includes a number of cavities between the connecting elements 4.

In this situation, it will be possible to go two ways for the construction of load-bearing or non-load-bearing walls. If the wall plates 1 are constructed with a stiffening casing around the cement/EPS-containing core so that constructive stiffening plate elements are formed, the wall construction will be able to be used as is. This is also the case if elements constructed in the same way as described above are used for the distance elements 4.

On the other hand, if the wall construction does not have the necessary rigidity to form a load-bearing and constructive wall, the spaces formed between the spacers 4 can be filled with an additional stiffening material such as cement or concrete or filling of cement-stabilized EPS.

In an alternative embodiment, some or all of the spacer elements 4 can be made of a fastening material such as wood or plastic in order to create an opportunity for attaching an inner or outer panel (not shown) to the elements 3.

For extra bracing in the corners of the wall construction, an H-beam or other similar bracing can be placed between the wall elements. However, this will not be necessary to form a full-fledged wall construction with the building kit according to the present invention.

Existing connecting elements 4 in a wall construction formed with the construction kit according to the present invention will, at joints between the wall elements 1 in the height direction, simultaneously form a stiffening and joining construction by the elements 4 extending across the joint over adjacent wall elements 1. Such a joining function will be necessary for high wall constructions where it is difficult to make the wall elements from one continuous piece. With such a joining construction, the grooves 2 for the joining elements 3,4 in the wall element 1 do not have to be continuous over the entire length of the wall element 1, but can only run a short distance down the inside of the wall element 1 so that a bottom is formed for the joining elements 3,4 when the building set is assembled. In such an embodiment, it would be preferred that the grooves 2 run downwards in the wall element 1 over a stretch corresponding to half the width of the joining elements 3,4 in order to thereby form a groove where the joining elements 3,4 also link two adjacent wall elements together 1.

Claims (5)

1. Building kit for the construction of buildings, and in particular wall structures in buildings, comprising at least two essentially parallel wall plate elements (1), characterized in that a number of grooves (2) are formed in the wall plate elements (1) on at least one side of the elements ( 1) which tracks (2) have a design so that the parts of the track (2) that lie inside the wall (1) are larger than the mouth of the track (2) which opens towards one of the surfaces of the road (1), where between the tracks (2) connecting elements (4) run in the wall plate elements (1), the outer edge area (3) of the connecting elements (4) being designed with an extended area that fits into the extended area of the wall track (2). 2. Building kit according to claim 1, characterized in that the outer edge area (3) and the grooves (2) have the shape of a T, a partial cylinder or a cone. 3. Building kit according to claim 1 or 2, characterized in that the grooves (2) in the wall element (1) run inwards from each edge of the wall element in a length that corresponds to a part, preferably half, of the width of the connecting elements (4). 4. Method for the production of a building using a building kit according to claim 1 or 2, characterized in that the wall plates (1) are assembled with the connecting elements (4) by placing the elements (4) in the grooves (2) in the elements (1 ) to form a connecting network of elements (4), whereby the space formed between the connecting elements (4) and the wall plates (1) is filled with a stabilized mixture of cement and a porous, artificial sofa-based insulation material such as expanded polystyrene (EPS), and wherein the mixture is allowed to harden to form a sustainable and insulating wall for use in the construction of a building. 5. Method according to claim 4, characterized in that the connecting elements (4) are mounted in connecting grooves (2) between adjacent and above wall elements (1).