FI20196054A1 - Moveable building and method for building a moveable building - Google Patents

Abstract

The mobile building has a floor slab and a number of parallel frameworks (12) which function as the building's frame structures. The frames have at least one upper frame bar (18), at least two vertical frame bars (16) and at least one lower frame bar with a lower surface. The bottom floor comprises at least two parallel profiled plates (10) in metal, which profiled plates are attached to the lower frame bars of the frame. The profiled plates function in the building as support structures for the bottom floor. The profiled plates also function as a foundation for the movable building through which the building's loads are led down to a load-bearing surface on the construction site.

Description

FIELD OF THE INVENTION The present invention relates to a mobile building comprising a subfloor and a plurality of parallel frame frames acting as building frame structures, the frame frames having at least one upper beam, at least two vertical and at least one lower beam having a lower surface. The invention further relates to a method for constructing a mobile building. - State of the art The use of element technology in building construction has become increasingly common. The advantages of elemental technology over on-site construction are faster construction time and better quality achieved through construction under factory conditions. At its best, a building can be manufactured at an element factory into an almost - finished building, which is taken as a whole to the construction site. This type of construction is particularly suitable for small buildings, the transport of which to the construction site does not require special arrangements. However, foundations must always be built on the construction site for complete buildings. Building foundations increases construction costs and extends construction time. The foundations of small buildings can be advantageously made as pillar foundations, e.g. with a spiral pile. However, the foundation of the columns must be taken into account in the frame structures of the building in order to transfer the loads of the building to the columns. This increases construction costs. FI20085549 discloses a prefabricated mobile building in which D 25 is a concrete plinth. The concrete plinth significantly increases the weight of the building, which makes it difficult to relocate the building and increases the relocation costs.

It is an object of the invention to provide a mobile building and a method for constructing a mobile building which can reduce the problems associated with the prior art. The objects of the invention are achieved by a building and a method characterized by what is stated in the independent claims. Some preferred embodiments of the invention are set out in the dependent claims.

BRIEF SUMMARY OF THE INVENTION The invention relates to a movable building comprising a subfloor and a plurality of parallel frame frames acting as building frame structures. The frame frames have at least one upper girder, at least two vertical girders and at least one lower girder with a lower surface. The lower base comprises at least two parallel metal corrugated plates, which corrugated plates are attached to the lower beams of the frame frames. The corrugated sheets function in the building as support structures for the lower floor, on which the floor of the building can be built. In addition, the corrugated sheets act as the foundations of the mobile building, through which the loads of the building are led to the load-bearing base at the construction site.

In a preferred embodiment of the movable building according to the invention, the corrugated sheets have surface planes defining the top side level and bottom planes defining the level of the lower side, and the lower surface of the lower trusses is against the surface planes of the corrugated sheets.

In another preferred embodiment of the movable building according to the invention, the building has a width and parallel corrugated sheets have substantially the entire width of the building. Preferably, the building has a length and the juxtaposed corrugated sheets have a length that is substantially equal to the length of the building. The plane formed of the corrugated sheets is thus substantially equal to the area delimited by the outer surface of the outer walls of the building to be built on the corrugated sheets.

In another preferred embodiment of the movable building according to the invention, the longitudinal direction of the corrugations of the corrugated sheet is substantially perpendicular to the longitudinal direction of the lower beams. The bending stiffness of the corrugated sheets is good in the longitudinal direction of the corrugations. When the lower beams are attached to the corrugated sheets in the transverse direction of the corrugations, sufficient rigidity is obtained for the level formed by the corrugated sheets also in the transverse direction of the corrugations. In yet another preferred embodiment of the mobile building according to the invention, the lower beams of the adjacent frame frames are spaced apart, and the corrugated sheets have a thermal insulation layer extending between the lower beams. S 30 - Preferably, the thermal insulation layer extends from the upper surface of the corrugated sheets to the upper surface of the lower beams.

In yet another preferred embodiment of the mobile building according to the invention, the thermal insulation layer comprises an extruded thermal insulation material, such as polyurethane foam. When hardened, the extruded polyurethane foam adheres to both the corrugated sheets and the lower beams.

The adhesive capacity of the extruded thermal insulation can be utilized in the building by fixing the corrugated sheets and the lower beams to each other either completely or at least partially by means of the extruded thermal insulation.

Alternatively or in addition, the thermal insulation layer may comprise thermal insulation sheets of hard thermal insulation material, such as polyurethane sheets and / or polystyrene sheets.

The thermal insulation boards can be placed on top of the lower, yet uncured thermal insulation layer formed by extrusion, whereby the thermal insulation boards adhere to the extruded thermal insulation layer.

In another preferred embodiment of the mobile building according to the invention, the lower edge of the at least one frame is a metal profile.

The lower barrier formed of a metal profile is particularly effective when the thermal insulation layer of the lower base is formed substantially entirely of a foamed thermal insulation material, such as polyurethane, and the lower barrier remains surrounded on at least three sides by the thermal insulation material.

In such a subfloor, a metal subfloor - is a less risk-free alternative than a subfloor made of wood material.

The invention further relates to a method for constructing a mobile building, which building comprises a subfloor and a plurality of frame frames serving as the frame structures of the building.

The frame frames have at least one upper girder, at least two vertical girders and at least one lower girder with a lower surface.

In the method, corrugated sheets are stacked in parallel on an assembly base, a plurality of frame frames are mounted in parallel on the corrugated plates at a distance from each other, and the frame frames are attached to the corrugated sheets from their lower beam.

The corrugated sheets attached to the lower girders thus form part of the lower floor structure of the building.

The frame rings can be fastened to the corrugated sheets with screws or nails that penetrate the corrugated sheet.

The fastening can be realized = by directing the screws or nails to pass through the lower beam from the upper surface of the lower beam N to the lower surface of the lower beam and further through the corrugated sheets below the corrugated sheets.

T Alternatively, the rows or nails can be directed obliquely through the second side surface of the lower girder and the lower surface to the corrugated sheet.

The attachment of the lower girders to the corrugated sheets can also be carried out. with the help of angle irons.

D In a preferred embodiment of the method according to the invention, the corrugated sheets have surface planes defining the top side level and bottom planes defining the bottom side level, and the lower surface of the lower trusses is placed against the surface planes of the corrugated sheets.

In another preferred embodiment of the method according to the invention, the building has a width and the corrugated sheets are stacked on the assembly base in an area substantially equal to the width of the building. In another preferred embodiment of the method according to the invention, the frame circumferences are mounted on the corrugated sheets so that the longitudinal direction of the corrugated sheet is substantially perpendicular to the longitudinal direction of the lower beams. In another preferred embodiment of the method according to the invention, a thermal insulation layer extending between the lower beams is formed on the corrugated sheets. Preferably, at least part of the thermal insulation layer is formed by extruding - into the corrugations of the corrugated sheets, i.e. into the upwardly opening gutters of the corrugated sheets, a foam-like thermal insulation material, such as polyurethane foam. Alternatively or in addition, at least part of said thermal insulation layer may be formed of hard thermal insulation boards, such as polyurethane sheets or polystyrene sheets. In another preferred embodiment of the method according to the invention - the ends of the corrugations opening into the lower surface of the corrugated sheets are filled with thermal insulation material. The advantage of the invention is that it significantly speeds up the production of a mobile building, which results in savings in labor costs. In addition, the invention has the advantage that the building to be moved is light, which makes it easier to move and transport the building as a whole to the construction site. This saves on transfer costs. BRIEF DESCRIPTION OF THE DRAWINGS The invention will now be described in detail. The description refers to N in the accompanying drawings, where = Cs. . . . oa. . NU O 25 - Figs. . Ca Co. . Figure 2 shows by way of example a building according to the invention in a cross-sectional view.

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DETAILED DESCRIPTION OF THE INVENTION In the method according to the invention, a plane is formed from the corrugated sheets 10 on a substantially flat assembly base. Figure 1a shows by way of example a plane formed of three corrugated sheets placed in parallel. The corrugated sheets used in the method are industrially manufactured building components commonly used in building construction, which have traditionally been used especially in the midsoles and tops of a building. The corrugated sheets are made by shaping a flat steel sheet into the desired corrugated cross-sectional shape. The wall thickness of the corrugated sheet can be 0.5-2.0 mm. The corrugated sheets shown in the figure have a so-called trapezoidal cross-section, but other cross-sectional shapes are also possible. Pleated sheets having a trapezoidal cross-section have surface planes defining the level of the top side of the pleated sheet and bottom planes defining the level of the bottom side of the pleated sheet. The length of the corrugated sheets is chosen so that it is substantially equal to the length of the building to be erected on top of the corrugated sheet plane. The number of corrugated sheets is chosen so that the width of the corrugated sheet plane is substantially equal to the width of the building to be erected on top of the corrugated sheet plane. The width of the corrugated sheet plane can be adjusted to suit by narrowing at least one corrugated sheet and / or changing the overlap width of adjacent pleated sheets. A plurality of factory-made frame frames 12 are mounted in parallel on the corrugated sheet plane formed in the method according to the invention (Fig. 1b). Frame frames are known building components commonly used in detached house construction. Typical building frame frames have a lower bracket 14 with a vertical 16 attached to each end and at least one upper bracket 18 attached to the upper ends of the verticals. The frame frames shown in Figure 1b have two upper-> 25-rafters 18, which are fastened to each other at their ends by means of an angle piece, so that N they form a so-called gable roof support structures. Preferably, the lower beams, the upper beams N and the vertical beams are wooden dogs connected to each other by nail plate joints. Alternatively, at least the lower perimeter of the body circumference may be a metal profile made of sheet metal with a web part comprising slit-like holes, both flanges having a flange part. Such a so-called. the thermorank is a well-known building component used in the frame structures of building D.

O 2 Frame frames are mounted on the corrugated sheets so that the longitudinal direction N of the lower beams is perpendicular to the longitudinal direction of the corrugated sheet and the lower surfaces of the lower beams abut the surface planes of the corrugated sheets. The lower braces are fastened to the corrugated sheets with screws or nails. The screws or nails can be directed to the corrugated sheets perpendicularly through the upper surface and the lower surface of the lower beams or obliquely through the side surface and the lower surface of the lower beam. The frame perimeters are supported on the corrugated sheets in a vertical position as shown in Figure 1b by temporary support structures not shown in the figure. After erecting the frame frames 12, a thermal insulation layer 20 is formed on the corrugated sheets, extending from the upper surface of the corrugated sheets 10 between the lower beams 14 (Figure 1c). The portion of the thermal insulation layer against the corrugated sheets is formed of polyurethane foam which is extruded to the bottom of the grooves of the corrugated sheets 10. As it expands, the polyurethane completely fills the upwardly opening folds of the corrugated sheets, i.e. the gutters, and rises between the lower beams 16 above the surface levels of the corrugated sheets. As it cures, the polyurethane adheres firmly to both the surface of the corrugated sheets and the lower portions, securing the corrugated sheets and lower portions together. The polyurethane can be applied to the corrugated sheets to such an extent that the level of the upper surface of the expanded polyurethane layer extends well above the level of the lower surface of the lower beams, even to the level of the upper surface of the lower beams. In this case, the thermal insulation layer is formed entirely of extruded foamed polyurethane. Alternatively, the foamed polyurethane may be formed into a layer of polyurethane extending slightly above the level of the top surface of the corrugated sheets, on which one or more layers of rigid thermal insulation sheets 22 are mounted (Figure 1d). The thermal insulation sheets may be polyurethane sheets or polystyrene sheets and may have an aluminum foil on one or both surfaces. The thermal insulation boards can be installed in place before the extruded polyurethane has hardened, so that they adhere to the extruded polyurethane over their entire surface area. When the thermal insulation layer has hardened sufficiently, the building frame is largely complete. The verticals 16 of the frame frames then form the frame posts of the long walls> 25 - the outer walls of the building and the upper girders 18 form the load-bearing structures of the roof of the building.

N 3 The building completed from now on proceeds according to the conventional, 7 known construction method. Frame posts are installed on the end walls of the buildings and thermal insulation is installed between the frame posts. A door 24 and x 30 windows 26 are installed in the walls in their designed places and the walls are clad with 3 surface claddings on both sides. Correspondingly, a thermal insulation D is installed on the roof of the building, between the upper beams, a surface cladding is installed on the inner surface of the roof and a water roof 28 is built above the upper beams N. A suitable floor covering is installed on the floor inside the building. Simultaneously with the thermal insulation and upholstery work on the inside, the HVAC installations of the building will be carried out.

The ends of the cavities defined by the lower surface of the corrugated sheets 10 and the assembly base opening to the ends of the building can be covered by extruding polyurethane foam at the ends of the cavities, which, when expanded, clogs the ends of the cavities. A plastic film can be applied to the assembly substrate prior to stacking the corrugated sheets on top of the substrate so that polyurethane extruded into the downwardly opening gutters of the corrugated sheets does not adhere to the assembly substrate. The building is then ready to be moved to the construction site (Figure 1e). Covering the ends of the downwardly opening corrugations can also be done after the building has been moved to the construction site. Figure 2 shows by way of example a cross-sectional view of a building manufactured by the method according to the invention - moved to the construction site. Prior to the transfer of the building, the construction site has been prepared by performing conventional excavation work and forming a compacted gravel or crushed layer and a frost insulation layer 32 on the construction site. The frost insulation layer can be formed above or below the crushed layer. It is essential that a non-depressed base 30 is formed on the construction site - i.e. a flat surface on which the building can be moved. The loads of the transferred application, i.e. the unladen weight, the weight of the furniture and persons inside the building and the snow load of the roof, are transferred to the base 30 via the corrugated sheets 10.

- In the embodiments shown in the figures, the corrugated sheets are formed into one corrugated sheet plane, on which the frame circumferences are fastened. In a preferred embodiment of the invention, the building is implemented in such a way that two overlapping corrugated board planes are formed on the assembly base, which are fastened to each other with screws or rivets. Preferably, the corrugated sheets of the overlapping corrugated sheets are perpendicular to each other, the corrugated sheets having a high transverse bending stiffness.

= After forming the corrugated sheet plane, N frame frames are attached to the top corrugated sheet as described above. Thereafter, the construction of the building il proceeds as described above.

z The use of two overlapping pleated = 30 plate plates in a direction perpendicular to each other improves the rigidity of the entire subfloor of the building. In addition, D has a structural height of two overlapping corrugated sheet levels that is twice that of one of the 3 corrugated sheets, thereby increasing the building height of the building.

O N The building according to the invention described in the above embodiments alone forms an entire building or a building frame. It is clear that the buildings according to the invention can be connected together on a construction site,

I created them together to form one building or building complex. The individual building according to the invention then does not form an entire building, but a part of the entire building. Some preferred embodiments of the portable building and method according to the invention have been described above. The invention is not limited to the solutions described above, but the inventive idea can be applied in various ways within the limits set by the claims.

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Reference number list: corrugated sheet 12 frame perimeter 14 lower girder 16 - vertical 18 - upper girder thermal insulation layer 22 thermal insulation board 24 - door 26 window 28 - water roof base 32 - iron insulation o

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Claims (1)

Claims A mobile building comprising a lower base and a plurality of parallel frame frames (12) acting as building frame structures, the frame frames having at least one upper girder (18), at least two vertical (16) and at least one lower girder (14) having a lower surface , characterized in that said lower base comprises at least two parallel metal corrugated plates (10), which corrugated plates (10) are attached to the lower beams (14) of the frame frame (12). A building according to claim 1, characterized in that the corrugated sheets (10) have surface planes defining the top side level and bottom planes defining the bottom side level and the lower surface of the lower girders (14) is against the surface planes of the corrugated sheets (10). Building according to Claim 1 or 2, characterized in that the building has a width and the corrugated sheets (10) arranged in parallel have substantially the entire width of the building. Building according to one of Claims 1 to 3, characterized in that the building has a length and the corrugated sheets (10) arranged in parallel have a length which is substantially equal to the length of the building. Building according to one of Claims 1 to 4, characterized in that the longitudinal direction of the corrugations of the corrugated sheet (10) is substantially perpendicular to the longitudinal direction of the lower beams (14). Building according to one of Claims 1 to 5, characterized in that the lower girders (14) of the adjacent frame frames (12) are spaced apart and that the corrugated sheets (10) have a thermal insulation layer (20) extending between the lower girders (14). A building according to claim 6, characterized in that the thermal insulation layer (20) extends from the upper surface of the corrugated sheets (10) to the upper surface of the lower beams (14). Building according to Claim 6 or 7, characterized in that the thermal insulation layer (20) comprises an extruded thermal insulation material, such as polyurethane foam. Building according to one of Claims 6 to 8, characterized in that the thermal insulation layer (20) comprises thermal insulation boards (22) made of hard thermal insulation material, such as polyurethane sheets and / or polystyrene sheets. Building according to one of Claims 1 to 9, characterized in that the lower pair (14) of the at least one frame (12) is a metal profile. A method of constructing a mobile building comprising a subfloor and a plurality of frame frames (12) serving as frame structures, the frame frames (12) having at least one upper beam (18), at least two vertical (16) and at least one lower beam (14) having lower surface, characterized in that in the method - corrugated sheets (10) are stacked side by side on the assembly base - a plurality of frame frames (12) are mounted in parallel on the corrugated sheets (10) at a distance from each other, and Method according to Claim 11, characterized in that the frame rings (12) are fastened to the corrugated sheets (10) by means of screws or nails which pass through the corrugated sheet (10). Method according to Claim 11 or 12, characterized in that the corrugated sheets (10) have surface planes defining the top side level and bottom planes defining the bottom side level, and the lower surface of the lower brackets (14) is placed against the surface planes of the corrugated sheets. Method according to one of Claims 11 to 13, characterized in that the building has a width and the corrugated sheets (10) are stacked on an assembly base - in an area substantially equal to the width of the building. Method according to one of Claims 11 to 14, characterized in that the frame circumferences (12) are mounted on the corrugated sheets (10) in such a way that the longitudinal direction of the corrugated sheet (10) is substantially perpendicular to the longitudinal direction S of the lower beams (12). Method according to one of Claims 11 to 15, characterized in that a thermal insulation layer (20) extending between the lower beams (14) is formed on the corrugated sheets (10). a x 17. A method according to claim 16, characterized in that at least 3 parts of the thermal insulation layer (20) are formed by extruding a foam-like thermal insulation material, such as polyurethane foam, into the S 30 corrugations of the corrugated sheets (10). Method according to Claim 16 or 17, characterized in that at least part of the thermal insulation layer (20) is formed from hard thermal insulating sheets (22), such as polyurethane sheets or polystyrene sheets. Method according to one of Claims 11 to 18, characterized in that the ends of the corrugations opening in the lower surface of the corrugated sheets (10) are filled with thermal insulation material. oO O OF N + O I a a < LO O O o O OF