NO333279B1 - A modular system for building buildings, comprising prefabricated building elements. - Google Patents

Abstract

The present invention relates to a modular system for the construction of buildings, for example residential houses, where the system comprises a number of elongated and insulated building elements, which building elements are made up of at least one inner and outer cladding layer and between the inner and outer cladding layers a layer of filling material is arranged. The layer of filling material can be made of polyurethane. In the layer of polyurethane, there is also at least one layer of a fire-retardant material. The elongated building elements are further adapted in their height and width direction to be connected with a number of insert elements, in order to assemble the elongated and load-bearing building elements into the walls of a building. floor and ceiling.

Description

The present invention relates to a modular system for the construction of buildings, such as residential houses etc., and more particularly the present invention relates to prefabricated building elements that are used during such construction.

So-called modular buildings are well known within the construction industry. Typically, such buildings will comprise a larger or smaller number of separate parts and/or elements that are prefabricated in a factory and which are then transported to a construction site, to be assembled on the construction site itself. The parts and/or elements can, for example, be entire wall sections, floors, roofs, completely or partially finished modules, comprising several assembled walls with roof and/or floor layers, etc., where the various parts and/or elements when assembled will form a building . This modular solution means that the prefabricated parts and/or elements can be checked in a better way at the factory itself, that they can be equipped with ready-made cables, sockets, they can be painted, wallpapered etc., where this facilitates the assembly of the building on the construction site.

Such modular buildings have a large number of areas of application. They are often used as short-term or long-term facilities as they can be set up and taken down relatively quickly. They can also be used as permanent buildings. Examples of what such modular buildings can be used for include schools and classrooms, hospitals, residential buildings and industrial buildings.

However, the prefabricated parts and/or elements are usually manufactured as larger units, for example as entire walls or entire rooms, where this means that larger vehicles must be used to transport the parts and/or elements to the construction site, and that cranes must also be used , more people and equipment when assembling the parts and/or elements. The prefabricated parts and/or elements will also sometimes have to be adapted further (cut to length, cut, insulated etc.) on the building site itself, whereby more time must necessarily be spent on assembling the building.

In recent times, there has also been an ever-increasing focus on the environment and climate, where this has led to changed requirements and criteria for the construction of buildings; this has led to regulations and rules already being changed and will be changed further in the future in relation to the degree of emissions (for example C02 emissions) in the various manufacturing processes for the manufacture of various building elements, in relation to improved climate in the buildings and in relation to materials used in such a construction process.

Among other things, the above has led to a new Norwegian set of regulations on requirements for the insulation of various buildings, where this set of regulations came into force from 1 August 2009. Among other things, this has led to the requirements for the heat insulation of the various buildings becoming stricter, so that there is less heat loss, whereby less electricity or oil, wood, etc. is used when heating the building. As a result of this, greater demands are placed on the materials used in the building.

A great many buildings in Norway today are wholly or partly made of wooden materials, as wood has traditionally been considered to have good insulating properties. However, compared to today's modern insulation materials used in homes and buildings, wooden materials will be less suitable for preventing heat flow in a building. When wooden materials are used in a building, there will be a significant loss of heat in a home or building through wall studs, beams, rafters or the like.

A purpose according to the present invention is therefore to provide a modular system for the construction of buildings, where one or more disadvantages of the known technique are eliminated or in any case reduced.

Another purpose according to the present invention will be to provide a modular system for the construction of buildings, where the modular system comprises prefabricated building elements.

A further purpose of the present invention will be to provide a modular system for the construction of buildings, where the building elements are isolated.

These purposes have been achieved with a modular system for the construction of buildings as stated in the subsequent independent claim, where further features of the invention emerge from the non-independent claims and the description below.

The present invention relates to a modular system for the construction of buildings, for example residential buildings, where the system comprises a number of prefabricated building elements. The prefabricated building elements are load-bearing, elongated and insulated and comprise at least an inner and outer cladding layer, and between this a layer of filler material arranged, in which layer of filler material at least one layer of a fire-retardant material is arranged. The elongated building elements are further, according to the present invention, in their height and width adapted to be connected with a number of insert elements, in order to assemble the elongated, load-bearing and insulated building elements.

In a preferred embodiment of the present invention, the prefabricated elongated, load-bearing and insulated building elements in the modular system are produced in the same length and width, whereby they must be cut and trimmed in relation to the building's doors, windows, etc. However, it should be understood that the prefabricated the building elements can also be produced in different length and/or width ratios, so that a number of building elements are fully adapted to be able to form the building's doors, windows etc.

The building elements' inner and outer cladding layers preferably consist of chipboard and/or veneer boards, which chipboard and/or veneer boards comprise a number of layers. In an alternative embodiment of the present invention, however, the inner and outer cladding layers could also consist of a single layer, for example of plank boards or similar. It is also conceivable that the building elements' inner and outer cladding layers can be made up of several different materials, which together form this inner and outer cladding layer.

The layer of filling material preferably consists of a polyurethane foam, as under a

manufacturing process of the building elements is filled in the space between the inner and outer cladding layer. How thick the layer of filling material should be will vary depending on the area of use of the building elements, for example whether the building elements are used as external walls, partial walls, lightweight walls, etc., as well as what insulation you want to achieve. Different materials can also be added to the layer of filling material, so that, for example, a desired "stiffness" or sound insulation in the building can be achieved. The layer of filling material will also essentially be arranged over the entire length and width of the building element.

The building elements are preferably prefabricated with one or more penetrations for wires, cables etc. which are to be passed through the building's walls, floor and/or roof, in order to facilitate the drawing and arrangement of the wires, cables etc. The penetration(s) are provided in the layer of filling material, and may for example include a pipe which, during the production of the building elements, is cast into the layer of filling material. However, it should be understood that the penetration(s) in the layer of filling material can also be provided without the use of pipes, as the penetration(s) can be designed after the building element has been produced or during the actual production. If pipes are used to provide the passage(s), each end of one or more pipes can be designed with suitable connection devices, so that pipes in two adjacent building elements can be connected easily and securely when assembling the building elements.

According to the present invention, the building elements are filled with a layer of filling material over essentially their entire length and width. This means that the layer of filling material will not extend over the entire length (height) and width of the building element, as an area at the building element's upper and lower edge will not be filled with the layer of filling material. This is because the building element must cooperate with an upper and lower sleeper, which sleeper will then form a floor and roof sleeper in the modular system. The floor and roof joists will then be designed with an integrated step, where the integrated step will interact with the area of the building element's upper and lower edge that is not filled with the layer of the filling material, in order to juxtapose the building elements with the floor and roof joists, thereby to form a completely "closed" building element. The integrated step in the floor and roof joists will then project a distance into the building elements when the building elements and the floor and roof joists are assembled.

In a similar way, a building element, when viewed into the building element from above, will be designed with a number of recesses between the inner and outer cladding layer and made of filler material, in which recesses a number of insert elements are arranged, in order to connect two adjacent building elements, and/or to increase the rigidity of the construction. This arrangement means that two adjacent building elements will then be connected by at least one common insert element which is arranged at least on one side of the building element (for example between the inner cladding layer and the layer of filling material).

However, a building element according to the present invention is preferably designed with recesses at both ends and on both sides of the cladding layer and the layer of filling material, whereby two adjacent building elements are assembled using two common insert elements, one insert element arranged on each side of the layer with the filling material.

The recesses will also be able to be arranged over all or parts of the building element's length and/or width.

In a preferred embodiment of the present invention, each building element is designed with a recess in each of its corners, where each recess extends a length in the width of the building element and the entire length (height) of the building element. In addition to this, each building element is designed at one end with a transverse recess, where this transverse recess runs between the recesses in the corners and also throughout the length (height) of the building element.

Furthermore, in relation to a preferred embodiment of the present invention, at least one layer of a "fire-retardant" material will be arranged in the layer of the filling material, in order to prevent or delay a fire. The layer of the fire-retardant material can, for example, consist of a chipboard and/or veneer board. The chipboard and/or veneer board will then extend the entire length of the layer with the filling material. However, it should be understood that at least one layer of fire-retardant material can also be made of materials other than a chipboard and/or veneer board, for example a plasterboard or equivalent, alternatively several different fire-retardant materials can be combined to achieve the desired effect. The different layers of fire-retardant materials can then be assembled into a composite layer, or they can be arranged at a distance in relation to each other, over the thickness of the building element (ie between the inner and outer cladding layers).

The modular system according to the present invention also comprises a floor and roof rest. In a preferred embodiment of the present invention, the floor and roof sleepers comprise two spaced wooden blanks, where a filling material is arranged between the wooden blanks. The filling material is, as for the building elements, preferably polyurethane.

The floor and roof sleepers are preferably produced with the same width as the elongated building elements, but they can also be produced with a larger or smaller width.

The filler material in the floor and roof sleepers will, in relation to cooperating with the upper and lower area of the building elements that are not filled with the layer of filler material, be designed to extend beyond the "height" of the wooden blanks, so that an integrated step is formed on one side of the floor and roof sleepers. This integrated step, which is constituted by the layer of the filling material, will, when the floor and roof sleepers are "attached" to the building elements, protrude into the building elements, so as to form "completely" closed and "airtight" building elements.

The building elements and the floor and roof joists according to the present invention are preferably produced in suitable forms, where the shapes are designed to form the building elements' various recesses, the floor and roof joists' integrated steps, etc. When manufacturing the building elements and the floor and roof joists, the inner and outer cladding and at least one layer of the fire-retardant material in the building elements, or the wooden blanks in the floor and roof sleepers are arranged in the suitable form, the form will then be closed and then the layer of the filling material (e.g. polyurethane foam) will be added to the closed form. Heat will then be applied to the molds to dry and harden the layer of filling material.

Through the present invention, a modular system for the construction of buildings has thus been provided, where the building elements, which are both used to create the building's walls, roof and floor, are preferably produced essentially identically, in a similar way to the way the floor and roof joists are produced as identical elements. This will result in a cheaper and simpler production of the building's various elements, as there is no need to produce a larger number of different elements.

Other advantages and distinctive features of the present invention will be clear from the following detailed description, the attached drawings and subsequent claims, where Figure 1 shows a number of building elements according to the present invention which are assembled to form a corner wall in a building, Figure 2 shows a number of building elements according to the present invention assembled to form a roof and/or floor in a building, seen from the side,

Figure 3 shows details of the corner wall according to Figure 1, seen from above, and

Figure 4 shows a building element combined with a floor and roof support, seen from the side, where further details of the modular system are indicated.

Figure 1 shows a modular system for building buildings 1, where a number of building elements 2 are assembled to form a corner in a building, for example a residential building. The building elements 2 are connected to a floor sleeper 3 and a roof sleeper 4. The floor and roof sleepers 3, 4 are produced as elongated elements, so that they can connect a large number of building elements 2. As will be understood, then the floor and roof sleepers 3, 4 then had to be adapted to the number of building elements 2 they are to connect. In the embodiment shown in Figure 1, the floor and roof sleepers 3, 4 and the building elements 2 are produced with the same thickness/width, but it should be understood that they can also be designed with different thickness/width.

A building element 2 comprises an inner and outer cladding layer 5, 6, see also Figures 2 and 3, where the inner and outer cladding layer in the embodiment shown is made up of a chipboard or veneer board. A layer of filler material 7 is arranged between the inner and outer cladding layers 5, 6, which layer of filler material 7 is made of polyurethane.

Each building element 2 is further designed with a number of recesses 8, 9 over all or part of its length and/or width extent, where these recesses 8, 9 are provided during the manufacture of the building elements 2.1 the recesses 8 will be arranged when the building elements 2 are assembled insert elements 10, in order to "connect" two adjacent building elements 2. In a similar way, insert elements 11 will also be arranged in the recesses 9, where the purpose of the insert elements 11 is to stiffen the assembled building elements 2.

The recesses 8 are arranged on each inside of the inner and outer cladding layers 5, 6, and at each end of the building element 2, in the layer of filling material 7 itself, while the recess 9 is only arranged at one end of the building element 2. By designing each building element 2 in this way, each recess 8, when two adjacent building elements 2 are put together, will form a "common" recess with a recess 8 in the adjacent building element 2, in which "common" recess 8 the insert element 10 is arranged.

As can also be seen from Figure 1, an insert element 11 is arranged in the recess 9 in each building element 2. The two insert elements 10, which are arranged essentially perpendicular to the insert element 11, will then together with the insert element 11 form an "I-beam" , which will stiffen the construction itself. However, the use of the insert elements 11 in a wall construction is not necessary, as the building elements are only subjected to an axial load.

When insert elements 10 are arranged in the recesses 8, and two adjacent building elements 2 are assembled, nails, screws, staples or similar will be used on each side of the building elements 2, so that two adjacent building elements 2 are connected to two insert elements 10, where the insert elements 10 are arranged on each side of the building elements 2.

If insert elements 11 are used, these will also be able to be "nailed" firmly to the insert elements 10.

Figure 2 shows, seen from the side, how the building elements 2 according to the present invention are put together to form a roof and/or floor in a building. The building elements 2 that are used to form the roof and floor of the building are identical to the building elements 2 that are used to form the walls of the building, but here it is preferred to use the insert elements 11, as this will form a "stiffer" construction. The insert elements 11 will then, together with the insert elements 10, form an "I-beam" over the entire length of the building element 2.

Figure 3 shows how a corner in a wall according to the modular system 1 according to the present invention is provided or "finished", as well as further details of the building elements 2. Here a building element 2 (the building element 2 which is located at the top and to the left in figure 3), which is to form a corner termination in the wall, is connected at one end in the manner indicated above with two insert elements 10, and optionally with an insert element 11 (not shown). At its opposite end, i.e. the end which forms the corner termination, an outer insert element 12 will be arranged, where this insert element 12 will "close" the building element 2 externally. The inset element 12 is then arranged across the building element 2, in the recesses 8, 9, partially covering the recesses 8. In a similar way, the building element 2 that extends from this corner element (downwards in the figure) will also begin with an outer insert element 12, which outer insert element 12 is arranged adjacent to the inner cladding layer 5 of the upper, left building element 2. The insert element 12 is then arranged across the building element 2, in the recesses 8, 9,

partially covering the recesses 8. Then this building element 2 and the subsequent, adjacent building element 2 will be assembled in the manner indicated above, with insert elements 10 being used to assemble and connect the building elements 2.

The building elements 2 shown in figure 3 will additionally comprise at least one layer of a "fire-retardant" material 13, where this at least one layer of "fire-retardant" material 13 is arranged in the layer of filler material 7. The at least one layer of the "fire-retardant" material 13 is made up of a chipboard or veneer board, plasterboard or equivalent, which chipboard or veneer board, plasterboard or equivalent will have the same extent over the width and height of the building element 2 as made of the filling material 7. This means that chips - or the veneer or plasterboard 13 will not be flush with a lower and upper edge of a building element 2, as this area is not filled with the filling material 7.

How the insert elements 10, 11, 12 are to be designed (i.e. length, width, thickness, material etc.), will depend on a number of parameters, such as loads the building elements 2 are exposed to, which materials are used in the building elements 2 etc. This will however, a specialist will know and it is therefore not described further here.

Figure 4 shows a building element 2 in cross-section, seen from the side, where the building element 2 has been erected and connected to floor and roof joists 3, 4. The floor and roof joists 3, 4 are then in a suitable way, for example by gluing, nailing or similarly connected to a room's floor and ceiling (not shown). The floor and roof sleepers 3, 4 are produced in significantly longer lengths than the width of the building elements 2. This means that the floor and ceiling joists 3, 4 must be adapted (sawed, trimmed etc.) in relation to the length and width of the room.

The floor and roof sleepers 3, 4 comprise two spaced wooden blanks 14, 15, where a layer of filler material is arranged between the wooden blanks 14, 15. The filler material is preferably the same filler material 7 that is used in the building elements 2.1 In the embodiment shown, polyurethane is used as filler material. As can be seen from the figures, the floor and roof sleepers 3, 4 will have the same width as the building elements 2, so that the outer edges of the wooden blanks will be flush with the cladding layer 5, 6.

The floor and roof sleepers 3, 4 will also be designed with an integrated step 16, which will extend over the height of the wooden blanks (when seen in the figure). This integrated step 16, when the floor and roof sleepers 3, 4 are "attached" to the building elements 2, will protrude into the building elements 2 upper and lower areas, so as to form "completely" closed and "airtight" building elements 2.

When assembling a building with the building elements 2 and the floor and roof joists 3, 4 according to the present invention, one will first start by assembling a number of building elements 2 which will form the building's floor. A building element 2 will be placed on the surface that will form the floor, after which an insert element 12 is arranged in the recesses 8, 9. This building element 2 then forms the first building element 2 in the floor. Insert elements 10 will then be arranged in the recesses 8, on the opposite side of the insert element 12, after which a new building element 2 will be pushed in towards the first building element 2.1 the second building element 2, there will also be an insert element 9 arranged, where the insert element 9 and the insert elements 10, by assembly of the first two building elements 2 will form an "I-beam" in the joint between the building elements 2. The first two building elements 2 will then be connected to each other by using nails, screws, staples or the like, in order to "nail" firmly the inner and outer cladding layers 5, 6 to the insert elements 10. This procedure will continue with successive building elements 2, until the entire floor is formed. The building element 2 which forms the end of the room will then be finished in the same way as the first building element 2 in the floor, by arranging an insert element 12 in the recesses 8, 9.

After the floor in the room has been formed, a floor sleeper 3 will be laid on the formed floor, after which a first building element 2 is raised and placed in the floor sleeper 3, to form a corner in a wall in the room. The first building element 2 will then, in a similar way to the first building element 2 in the floor, begin with an insert element 12. Then, on an opposite side of the insert element 12, insert elements 10 will be arranged in this building element's recesses 8, after which a new building element 2 is pushed in towards the first building element 2. The part of the insert elements 10, which protrudes from the recesses 8 in the first building element, will then be arranged in the recesses 8 in the adjacent building element 2. Now the two adjacent building elements 2 can be connected to each other through nails, screws, staples or similar. A similar procedure is repeated for each building element 2, until a first wall in the building has been created. The last building element 2 in the wall will then end with an insert element 12, so that a flat, outer surface is formed in this building element 2. The subsequent wall will then begin with an insert element 12 in the first building element 2 in this wall, after which the procedure for this wall will be the equivalent of the first wall. This is done for each wall in the room.

When all the walls in the room have been formed as described above, a roof sleeper 4 will be arranged at the upper end of the building elements 2, extending over the entire length of the wall. The procedure for assembling the floor will then be repeated, but now for the creation of the room's ceiling.

The building elements 2 are, as indicated above, preferably produced in the same lengths, whereby the building elements 2 must be cut and trimmed in relation to the building's doors, windows, etc. However, it should be understood that a number of building elements 2 can be prefabricated in already adapted lengths for the building's doors and /or windows. The invention is now explained with several non-limiting examples. A person skilled in the art will understand that a number of variations and modifications can be made to the modular system as described within the scope of the invention as defined in the appended claims. Although the description of the application describes the use of wood for the production of the elongated elements, it should be understood that other materials can also be used.

Claims (8)

1. A modular system for the construction of buildings, comprising prefabricated building elements, the system comprises a number of load-bearing elongated and insulated building elements (2), which building elements (2) are made up of at least one inner and outer cladding layer (5, 6) and between this arranged a layer of filling material (7), in which layer of filling material (7) at least one layer of a fire-retardant material (13) is arranged, characterized in that recesses (8) are arranged on each inside of the inner and outer cladding layer ( 5, 6) at each end of the building elements (2), in the filling material (7) itself, as two insert elements (10) when assembling two adjacent building elements (2) will be arranged in the two lying one above the other, in the longitudinal direction, the recesses (8), in order to connect said two adjacent building elements (2), where a further recess (9) is arranged at one end of the building elements (2), with an insert element (11) arranged in the recess (9) at assembly illing of said two adjacent building elements (2) together with the insert elements (10) will form a stiffening of the elongated and load-bearing building elements (2). 2. System according to claim 1, characterized in that the inner and outer cladding layers (5, 6) consist of a single layer or of a number of layers. 3. System according to claim 1, characterized in that the layer of the filling material (7) is polyurethane. 4. System according to claim 1 or 3, characterized in that the layer of filling material (7) is arranged essentially over the entire length and width of the building element (2). 5. System according to claim 3, characterized in that the layer of filling material (7) comprises different additive materials. 6. System according to claim 1, characterized in that the recesses (8, 9) are designed over all or parts of the length and width of the building element (2). 7. System according to claim 1, characterized in that the system further comprises floor and roof supports (3, 4), which floor and roof supports (3, 4) comprise two or more spaced wooden blanks (14, 15), where between the two or more spaced wooden blanks (14, 15) are arranged in at least one layer of filler material (7). 8. System according to claim 1, characterized in that the wooden blanks (14, 15) in the floor and roof sleepers (3, 4) comprise an integrated step (16).