NL2010903C2 - MODULAR SKELETON BUILDING SYSTEM FOR HOUSES. - Google Patents

Description

Title: Modular skeleton system for homes

The invention relates to a modular skeleton system for homes. More specifically, the invention relates to a skeleton system for homes in tropical and sub-tropical areas.

Modular systems are described, for example, in international patent application WO2012103133. This document shows a folding construction of a house with a butterfly roof. A drawback of such constructions is the lack of provisions for cooling and circulation. This house is therefore unsuitable for tropical and sub-tropical areas. In addition, this house also occupies a considerable space when folded, since the entire walls, roof and bottom are included in the folded package. Moreover, due to the various folding elements, this construction becomes complex and difficult to manufacture.

Thus, it is an object of the invention to provide a system which does not have the above-mentioned and / or other disadvantages or at least partially eliminates them while at least partly retaining the advantages thereof. A further object of the invention is to provide a skeleton building system that is simple to use, robust, easy to adjust and in which a relatively comfortable temperature can be maintained.

At least one of these and / or other objects is achieved with a modular skeleton system suitable for the manufacture of at least one house, the system comprising a series of profiles and a bearing profile provided with raised edges, the series of profiles comprising a number of uprights, comprises a first set of bearing beams and a second set of bearing beams, wherein the second set of bearing beams, when mounted, comprise upwardly directed bearing surfaces which make a specific angle with the horizontal plane, the uprights at the corner points and along the long sides of a rectangular base surface of the house can be placed whereby the first set of supporting beams can be placed at a specific distance from the top of the uprights substantially transversely of the rectangular base surface and substantially parallel to the short side of the rectangular base surface and wherein near the second set of supporting beams in the top of the uprights or that can be arranged parallel to the long sides of the rectangular bottom surface and substantially transversely of the first set of beams, wherein in the middle of the first set of bearing beams the bearing profile provided with upright edges is substantially parallel to the second set of bearing beams and substantially can be arranged transversely to the first set of bearing beams, such that the second set of bearing beams and the bearing profile provided with upright edges can together support a series of curved plates arranged at a specific inclined angle, such that it faces in the direction of the upstanding bearing profile provided with edges, which run downwards towards the center, wherein the bearing profile comprises bearing collars placed at a specific angle on the raised edges, wherein the curved plates on the bearing profile provided with raised edges can be placed at a mutual distance from each other such that the lower edges of the curved plates on either side in each case extend beyond a first upright edge of the support profile, so that rainwater can be collected on the curved plates placed at an inclined angle and can be guided into the support profile provided with upright edges, which in turn can collect this water and to a drain pipe can conduct.

By using a load-bearing profile, which serves as a water drain, the construction can be particularly simple and yet be sufficiently robust to provide a stable construction. Due to the specific angle and the open structure, a chimney effect can occur under the roof plates, which can create a slight underpressure in the interior of the home. This allows a circulation of air to be achieved, which can keep the temperature in the home at a pleasant level. This is partly caused by the fact that the ventilation light is sucked in from underneath the house, where a relatively lower temperature prevails.

The skeleton system according to the invention is a product that must be able to be produced and operated sustainably and is therefore based on an analysis of life cycle, flexible use, efficient energy use and adaptability. The distinctive quality of the skeleton system is the result of the use of, and the coherence between, a number of guiding principles. These are summarized below.

Firstly, a system separation, in particular a separation of systems with a different lifespan;

Secondly, a modular coordination where the design is based on a fixed dimensioning pattern;

Thirdly, industrial production, namely prefabrication, in parts, of the supporting structure;

Fourth, passive climate control, more particularly cooling and heating based on physical principles;

Fifthly, a free categorization and possibilities for expansion and adaptation, which can provide life-course stability.

The following components can be distinguished in a house built with the skeleton system according to the invention: first, the skeleton, which can be a lightweight steel support structure, which is (pre) fabricated in parts according to a fixed modular pattern. The floor and roof can be part of this. Secondly, the skin, that is to say an enclosing and therefore climate-separating construction, which in principle can be filled in as desired and is preferably composed of locally manufactured and available materials and raw materials. This by definition follows the modular dimensions. Thirdly, the organs: a minimum of installations that support the 'metabolism' or energy management of the home. This component can be connected to the local infrastructure and allotment. In the system according to the invention, a variable classification into "chambers" can be chosen by the end user, which is in principle separate from the support structure.

The first component, the support structure or the skeletal system according to the invention forms the core aspect of a home. The generic shape and dimensions of this determine the climate-technical "performance" of the home, as explained in more detail below. The system according to the invention can, due to the modular construction, provide the possibility for specific fillings, different facades, a diversity of floor surfaces and effects on the basis of different climatic conditions and cultural preferences.

The other components, namely the skin and organs, may be location-specific, but must be coordinated in relation to the dimensions and the bioclimatic principles of the skeletal system according to the invention. The structure of the system according to the invention can provide an interweaving of formal organization and production method such as allotment, industrial production and ownership and informal economy, for example locally produced façade parts, self-efficacy, recycling of building material, use of the home as a shop, etc.

By providing a modular skeleton system, the individual three systems present in a home can thus be: firstly the bearing structure or skeleton, which also includes the floor and roof, secondly the outer walls or the skin and thirdly the facilities or the organs are actually separated. It appears that these three separate systems each have their own specific lifespan. By strongly integrating this separation of these three systems into the design in advance, a sustainable solution for the provision and use of affordable homes can ultimately be obtained over the entire lifespan of the support structure. In addition, essentially only the supporting structure, the skeleton can be produced and shipped, while the walls, the roof, the floors, the partitions and the other facilities can be obtained and / or produced locally. As a result, the transport costs can be relatively low and, for example, a multiple number of systems can be loaded in a single container for a multiple number of homes. Furthermore, the advantage of such a construction is that a builder can build a house or at least the supporting structure for it within a period of a few days with the aid of a simple instruction video and a small amount of tools.

During the lifetime of the skeleton, the other two systems, the skin and organs, can be replaced several times, without having to break down, process or replace the carrying skeleton.

In the modular skeleton system, further beams can be arranged between the posts substantially parallel to the long side of the base at the level of the bearing beams. These beams are of particular advantage for attaching wall panels, doors, windows, frames and the like in the construction of the house.

A ceiling can be attached to and / or to the bottom flange of these beams and the aforementioned first set of bearing beams. This ceiling divides the space vertically into two compartments. This contributes to the passive climate control and reinforces the chimney effect in the upper space. As a result, the underpressure in the home can be strengthened, so that more circulation could take place. This ceiling also prevents the radiant heat from the roof from heating the living space.

The ceiling may comprise cladding, plastered panels, fiber boards, concrete fiber boards, plywood, gypsum boards, a tensioned cloth or a tensioned membrane and / or any other suitable ceiling material. If a fleece or cloth is used, it can be attached, for example, by means of ring eyelets to the lower flanges of the beams, which are arranged at a specific distance from the top of the uprights.

The cloth can herein comprise holes or flaps provided with mesh, which can for instance be arranged on the facade sides.

Providing these holes or valves allows air to flow out of the lower space, the living space into the upper space. The chimney effect of the sloping roof can be optimally utilized by arranging the holes or valves near the low-lying part of the sloping roof plates.

The specific distance between the top of the uprights and first set of bearing beams can be chosen such that the angle of inclination of the curved plates is less than 45 degrees and preferably less than 40 degrees. An angle around 35 degrees appears to provide good results. The angle could still be adjusted to local circumstances, such as latitude and local climate conditions. At the aforementioned angles, the amount of solar radiation can be used optimally for the intended chimney effect within the upper space in the home. Here the angle is chosen such that on the one hand the solar radiation is sufficient and on the other hand the chimney effect is sufficiently present. Too large an angle would benefit the chimney effect, but it would absorb so little sunlight that the natural draft could hardly occur. On the other hand, a completely horizontal roof is favorable for a maximum collection of solar radiation, however, no vertical transport of air can be obtained. It appears that at the selected angles the combination of both effects is relatively favorable.

A third set of bearing beams can be arranged between the posts at a specific distance from the ground level. By keeping a space under the floor of the house free, an additional cooling benefit can be obtained. To that end, a set of purlins can be arranged between the third set of bearing beams, substantially transversely of these bearing beams, to which floor parts can be fitted.

Ventilation openings may be provided in the floor sections. As a result, air is drawn into the living area from beneath the home, which can then flow away through the openings or flaps in the ceiling. As a result, the temperature during the day can be reduced to a pleasant level, so that a more pleasant stay in the home can be obtained without having to use, for example, an air conditioner. The holes may be provided with gratings or may comprise tubes which partly run through the ground or through a rainwater storage optionally located under the dwelling. By having these pipes run through the ground or through a water storage, this air can be additionally cooled, which can contribute to a pleasant indoor climate in the home.

The modular skeleton system can be built into a house, the walls, system walls, windows, doors and / or cladding between the third set of bearing beams and the first set of bearing beams and / or between the third set of bearing beams and the second set of bearing beams can be applied. The walls can be manufactured locally, and can consist of a wide variety of building materials. This includes wooden plates, wood fiber plates, gas concrete parts, plaster plates, metal plates, sandwich plates, masonry bricks, clay loam, boards and the like. By not necessarily shipping the walls and / or the roof plates and / or the floor parts in the modular system, considerable savings can be made in transport costs.

The uprights can be attachable to an anchor with a base plate. The anchoring can consist of poured concrete, possibly provided with protruding threaded ends, or by placing holes in the concrete after pouring into which mechanical or chemical anchors with threaded ends can be anchored.

Substantially rectangular fly screens can be arranged between the beams and the uprights and substantially triangular fly screens can be arranged between the beams, the uprights and the curved roof plates. A good ventilation of the house can be obtained through these screens. Furthermore, the mosquito nets can keep pests out.

The invention further relates to a method for manufacturing a house comprising the following steps to be carried out in any suitable order: Providing a modular skeleton building system, placing a series of foundation elements; placing the uprights on the foundation elements and bolting them with a base plate, for example by means of wire ends arranged in the foundation elements; arranging beams between the posts; arranging a bearing profile provided with raised edges on the beams; arranging purlins between the low beams; installing floor parts on the purlins; installing walls, doors, and / or windows between the beams; arranging fly screens between the second series and beneath them; arranging screens in the triangles formed by the top of the second series of beams, the top of the uprights and the raised edges of the profile; arranging a series of self-supporting curved plates at a specific angle extending on a first side beyond the bearing surfaces of the second series of beams and on a second side extending beyond bearing collars of the bearing profiles provided with upright edges; installing the ceiling between the lower flanges; the possible placement of partitions with possibly doors and / or windows.

This method is a particularly simple way of providing a well-ventilated and relatively cost-effective home, in which it is still pleasant to be in a tropical or sub-tropical climate.

The invention will be further elucidated with reference to embodiments shown in the drawing. In the drawing: figure 1 shows a schematic perspective view of a modular skeleton building system according to a first embodiment of the invention; figure 2 shows a schematic sectional view of a bearing profile with raised edges according to an embodiment of the invention; figure 3 shows a schematic sectional view of a bearing profile according to a further embodiment of the invention; figure 4 shows a schematic perspective detail view of the bearing profile with curved roof plates according to an embodiment of the invention; figure 5 shows a first schematic detail view in section through line X in figure 1; figure 6 shows a second schematic detail view in section through line X in figure 1; figure 7 shows a first schematic detail view in section through line Y in figure 1; figure 8 shows a second schematic detail view in section through line Y in figure 1 with an alternative embodiment according to the invention; figure 9A shows a schematic detail view in section through line Z in figure 1 with an embodiment according to the invention; figure 9B shows a schematic detail view in section through line Z in figure 1 with an alternative embodiment according to the invention; figure 10 shows a first schematic detail view in section through line W in figure 1 with an alternative embodiment according to the invention; figure 11 shows a second schematic detail view in section through line W in figure 1 with an alternative embodiment according to the invention; figure 12 shows a schematic sectional view of an alternative embodiment of the bearing profile according to figure 2; Figure 13 is a schematic perspective view of a home according to an embodiment of the invention; Figure 14 is a schematic perspective view of a home according to an alternative embodiment of the invention; Figure 15 is a schematic perspective view of a home according to another embodiment of the invention.

It is noted that the drawing is only a schematic representation of preferred embodiments of the invention. The drawing is by no means to be construed as limiting the invention. In the figures, the same or corresponding parts are indicated by corresponding reference numerals.

Figure 1 shows a schematic perspective view of a modular skeleton building system 1. In this system 1 six uprights 2 are placed on a rectangular base surface 5. Two uprights are placed in the middle of the long sides 6 of the rectangular base plane 5, and the remaining four uprights are placed at the corner points of the base plane 5.

In this embodiment the uprights are designed as I profiles (for example IPE 180). Foot plates 27 are attached to the uprights, with which the uprights can be attached to foundation blocks 24. This attachment can be made as mechanical or chemical anchors, which can be anchored in boreholes. Alternatively, the anchoring can also be designed as protruding threaded ends cast into the concrete of the foundation block 24.

Between the posts Between the posts 2, a first series of beams 3 are arranged parallel to the short sides 7 of the rectangular base surface 5, at a distance A from the top of the posts 2. These beams can also be designed as I profiles and can be attached to the flanges of the posts with end plates. This attachment can be carried out with bolts which can be guided and tightened through holes pre-drilled in the uprights 2 and the end plates of the beams 3. On the first series of beams 3, a bearing profile 8 provided with raised edges is placed near the center. In figure 1 this profile consists of two parts, which lie in the middle with their ends facing against each other and are supported there by the middle carrier 3.

The embodiment of the bearing profile 8 provided with upright edges is shown in a cross-sectional view in Figure 2. The profile comprises a bottom plate 13, with upstanding edges 11 on either side, on which bearing collars 12 are mounted at an angle α with the horizontal plane -in condition. The bearing profile provided with upright edges each comprises a wall 30 on the ends, so that this profile 8 forms an upwardly directed receiving space. It can be seen from Figure 4 that an opening 14 is provided in the bottom surface 13. Rainwater can be drained through this opening 14.

Figure 1 furthermore shows that a second set of profiles 4 is arranged between the uprights 2 along the long sides 6 of the rectangular base surface 5 on the upper edge of the uprights 2. A sectional view of these profiles 4 is shown in Figure 3. The profiles 3 can for instance be cold-formed profiles, which are provided with a bearing surface 15 which, in the mounted state, makes an angle α with the horizontal surface. The profiles 4 can for instance be connected to the flanges of the uprights 3 by means of bolts with the surfaces 31 and / or 32, or for example be connected to the surfaces 33 by means of corners with uprights 2 arranged on the web plates of the uprights 2. confirmed.

At a distance A from the top of the uprights 2, beams 16 are arranged in the direction parallel to the long side 6 of the rectangular bottom surface 5. The beams 16 are at the same height as the beams 3 and together form a frame surrounding the entire structure.

At a distance B from ground level 23 a series of bearing beams 21 are arranged parallel to the short side 7 of the rectangular bottom surface and a series of bearing beams 22 parallel to the long side 6 of the rectangular bottom surface 5. These beams 21, 22 serve as supports for the floors and walls of the dwelling as explained in more detail below.

Figure 4 shows a detail of the roof construction in a schematic perspective view. On the bearing surfaces 15 of the profiles 4 and the bearing collars 12 of the bearing profile 8, curved plates 9. Due to the curvature in these plates 9, they need no further support in addition to the dual support. This makes the plates self-supporting, as it were, which can keep the construction simple. In the mounted state, the curved plates 9 extend beyond the raised edges 11 of the support profile 8. This allows rainwater falling on the domed plates 9 to be led into the upwardly directed open space of the support profile 8, which then leads it to an opening 14 can lead. The rainwater can possibly be stored in a room or tank under the house.

Figure 5 shows a detailed cross-sectional view through line X as indicated in Figure 1. In this cross-section, a view of a middle upright 2 is presented, the flanges of this upright 2 being perpendicular to the plane of the drawing. The profile 4 in this figure is also directed perpendicular to the plane of the drawing, and shows the bearing surface 15 arranged at angle α, to which the curved plates 9 are fixed. Fillings 34 may be provided in the raised curves of the curved plates. These fillings 34 can effect a seal of the inside of the house with the outside world in order to prevent, for example, the ingress of insects.

A screen 28 is placed against the top of the profile 4 and extending to the top of the profile 16. This screen 28 may, for example, comprise a mesh mounted on a frame, optionally provided with blinds. Insect screens 28 can, for example, be attached to the profiles 4 and 16 by means of optionally angled aluminum strips. For example, fillings 34 in the form of trapezoidal plugs can be placed in the upright curves of the curved roof plates 9 in order to provide a better seal.

Windows 35 can be placed between the profiles 3 and 16 on the top side and the profiles 21 and 22 on the bottom side. These windows can, for example, be held in place by profiles 36 and / or 37 fixed to the profiles 3 and 16. The profiles 36 and 37 can for instance comprise extruded aluminum parts or consist essentially of these. At the bottom of the window 35, the window 35 can rest on a profile 38. The profile 38 can be provided with a lip 39, which can serve as a stop and positioning for the window 35, as shown in Figure 6. Here, the profile comprises a square open chamber 40 and a horizontal flange 41. The horizontal flange 41 rests on the profile 22 and can, for example, be glued or otherwise fixed to it. The window 35 can comprise a glass plate 42 which is enclosed in a frame 43.

Between the profiles 16 and 3 a ceiling 17 in the form of a cloth or fleece is arranged, which for example is attached to the lower flanges 3A and 16A with the aid of bolts 19 and nuts 20 by means of ring eyelets arranged in the cloth. The ceiling can also be made from alternative building materials, such as, for example, fiberboard, plasterboard, plywood, plywood, MDF, HDF, LDF, and / or other suitable building materials. The ceiling can also comprise system ceiling plates of plaster, wood fibers and the like, which are contained in a frame.

Closable openings can be provided in the ceiling for better ventilation. These openings can for instance be closed or opened by means of valves, preferably by hand.

Figure 6 shows in detail that upright 2 is mounted on a foundation block 24 via a base plate 27. The foundation block and optionally the distance between the bottom plate 27 and the mounting of the beams 21 and 22 are such that the beams 21 and 22 are positioned at a distance B from the ground level. As a result, there is underneath substantially the entire home a free space with a height B, under which free air can flow.

Purlins 25 are arranged between the profiles 21. The purlins 25 can for instance be cold-formed profiles, which are attached to the profiles 21 by means of corner connections. Due to additional stability, the outer purlins can be attached to the profiles 22 by means of angled profiles 44.

Figure 7 and Figure 8 show a section through the line Y in Figure 1. In this section, the girder 3 is perpendicular to the plane of the drawing and the view on the outside of the upright is edge 11 of the bearing section 8. In this figure the underside of vaulted roof plates 9A and the top of the vaulted roof plates 9B are shown. On the girder 3 there is a substantially triangular-shaped screen 29, which rests on the girder 3 on the underside and runs at the top under the slope angle α along the underside of a roof plate 9A.

The screen can herein be connected to the roof plate 9 by means of an angled profile 45.

In Figs. 7 and 8, bars 46 are provided for the windows 35 standing on the inside of the house. These can be connected at the top with profiles 3 or 16 and at the bottom with profiles 21 and / or 22. For reinforcement, these bars can, for example, still be mutually connected halfway for additional robustness.

The purlins can be fastened to the profiles 21 with angular connections, and can rest on a plate 48 for additional strength, which plate is for instance attached to a lower flange of the profiles 21 by means of a bolt 49.

In addition, the profiles 21 and 22 on the outside on the lower flange can comprise a downwardly welded-on profile 47, which can prevent rainwater from penetrating into the space under the house due to wind pressure.

Floor parts 26 are provided on the purlins 25. These floor parts can be manufactured from various materials and, for example, a concrete casting floor can also be applied to the plates 26. A floor heating system could possibly be integrated in such a screed floor.

Figure 9A shows a cross-sectional view through line Z in Figure 1. Here, the bearing profile 8 is parallel to the plane of the drawing. In this figure, two carrier profiles 8A and 8B are placed with the ends facing each other, such that the walls 30A and 30B of the two carrier profiles 8A and 8B run parallel and abut, respectively. A cap 50 can be placed over the upper edges of the adjacent walls 30A and 30B. This cap 50 can prevent any water from entering between the walls 30A and 30B. This cap 50 can be screwed onto the walls 30A and 30B.

An alternative connection between the two support profiles 8A and 8B is shown in Figure 9B. Here, the walls 30A and 30B of the support profiles 8A and 8B are absent, respectively, and one of the two support profiles 8A is provided with a welded-on strip 51 extending in the direction of the bottom surface 13A, the upstanding edges 11A and optionally the bearing collars 12A. This strip 51 can extend over a part of the bottom surface 13B, the raised edges 11B and optionally the bearing collar 12B of the bearing profile 8B. Between the strip 51 and the parts of the support profile 8B, a sealing material such as, for example, a kit or a compand band or a corresponding seal can be provided. The strip 51 can be connected to the profile 3 by means of a bolt 52 provided with a rubber ring. Here, the bolt 52 can extend through both the material of the welded-on strip 51 of support profile 8A and through the bottom plate 13B of support profile 8B, and thus achieve a good seal between the two support profiles 8A and 8B.

Figures 10 and 11 show detailed views through line W in Figure 1. In these figures, the profiles 3 and 21 are perpendicular to the plane of the drawing. In this embodiment the wall is formed by a prefabricated gas concrete slab 58, which is arranged between the beams 3 and 21. At the top, below girder 3, the gas concrete slab 58 is held in place by means of profiles 36 and 37, as shown in Figure 10. On the underside, the aerated concrete slab can be mounted against, for example, a set aluminum profile 57. This set profile 57 may comprise a first edge 53, a flat part 54 and a second edge 55. The first edge 53 can abut the outer edge of the upper flange of beam 21 and the second edge 55 can serve as a stop for the gas concrete slab 58.

A resilient seal 59, such as, for example, a cellular band, may be provided between the profiles 36 and 37 on the upper edge of the gas concrete slab 58. The resilient seal 59 can compensate for any inaccuracies in the structure and / or in the gas concrete slab 58, and can at the same time exert a resilient force on the gas concrete slab 58, so that it remains substantially in its desired position during assembly. The strips 36 and 37 and the set profile 52 can fix the gas-concrete slab 58 in cooperation.

The aerated concrete slab 58 can have a diameter of, for example, 10 cm and can be fixed by means of a screw 56 from the bottom, by the upper flange of the beam 21.

Figure 12 shows an alternative embodiment of the bearing profile 8. In this figure the bearing profile comprises splashing edges 60 which can prevent splashing of rain water against the connection between the bearing collars 12 and the roof plates 9.

Figure 13 shows a house built using the modular skeleton system according to the invention. A roof is attached to the house, which can serve as a carport or veranda.

In figure 14 two dwellings are connected in the longitudinal direction, and in figure 15 a dwelling is provided with a floor. Alternative circuits are also possible, wherein possibly the bearing profiles 8 are oriented not in the longitudinal direction but in the width direction of a rectangular base surface. The base can also have a square shape.

It is noted that the invention is not limited to the exemplary embodiments discussed above. For example, in the figures the orientation of the uprights is such that the flanges of the profiles are oriented substantially in a direction parallel to the long side 6 of the rectangular base surface 5. Alternatively, the flanges can similarly also be directed in a direction parallel to the short side 7 of the rectangular base surface 5.

Although the height between the underside of the purlins 25 and the ground level is mainly determined by the height of the poured foundation blocks, the height of the connection between the uprights 2 and the beams 21 and 22 can also be adjusted such that the foundation blocks no longer, or hardly ever, extend from ground level.

Such and other variants will be clear to those skilled in the art and are understood to lie within the framework of the invention as set forth in the following claims.

List of reference numbers 1. Skeleton system 2. Upright 3. Bearing beam 3A. Bottom flange 4. Bearing beam 5. Rectangular base 6. Long side of the base 7. Short side of the base 8. Upright bearing profile 8A. Support profile 8B provided with raised edges. Support profile provided with upright edges 9. Curved plate 10. Lower edge 11. Upright edge IIA. Upright edge IIB. Upright edge 12. Load-bearing collar 13. Bottom surface 13A. Bottom surface 13B. Bottom surface 14. Opening 15. Bearing surface 16. Beam 16A. Lower flange 17. Ceiling 18. Washer 19. Bolt 20. Nut 21. Girder 22. Girder 23. Ground level 24. Foundation block 25. Purlin 26. Floor section 27. Base plate 28. Mosquito screen 29. Hor 30. Wall 31. flat 32. Flat 33 Flat 34. Stop 35. Window 36. Profile 37. Profile 38. Profile 39. Lip 40. Chamber 41. Flange 42. Glass plate 43. Frame 44. Angled strip 45. Angled strip 46. Grating 47. Affected strip 4 8 Carrying strip 49. Bolt 50. Cap 51. Welded strip 52. Bolt 53. Edge 54. Flat part 55. Edge 56. Screw 57. set profile 58. Aerated concrete slab 59. In-spring seal 60. Splash edge A. Distance B. Distance W Line X. Line Y. Line Z. Line ex. Corner

Claims (14)

A modular skeleton system (1) suitable for the manufacture of at least one house, the system comprising a series of profiles (2,3,4) and a bearing profile (8) provided with raised edges, the series of profiles comprising a number of uprights (2), a first set of load-bearing beams (3) and a second set of load-bearing beams (4), wherein the second set of load-bearing beams (4) comprise upwardly supported bearing surfaces (15), which have an angle (a) with making the horizontal plane, wherein the uprights (2) can be placed on the corner points and along the long sides (6) of a rectangular base surface (5) of the house, wherein at a distance (A) from the top of the uprights (2) the first set of bearing beams (3) can be arranged substantially transversely of the rectangular base surface (5), and substantially parallel to the short side (7) of the rectangular base surface (5) and wherein near the top of the uprights ( 2) the second set of bearing beams (4) in h cause parallel to the long sides (6) of the rectangular bottom surface (5) and to be arranged substantially transversely to the first set of beams (3), wherein in the middle of the first set of bearing beams (3) the bearing profile provided with upright edges (8) can be arranged substantially parallel to the second set of bearing beams (4) and substantially transversely to the first set of bearing beams (3), such that the second set of bearing beams (4) and the bearing profile provided with raised edges (8) can together support a series of curved plates (9) arranged at an inclined angle (ex), such that they run towards the center in the direction of the bearing profile (8) provided with upright edges, the bearing profile (8) ) comprises supporting collars (12) placed at an angle (ex) on the upright edges (11), wherein the curved plates (9) can be placed at a mutual distance from one another at the bearing profile (8) provided with upright edges, that the o The lower edges (10) of the curved plates (9) on each side extend beyond a first upright edge (11) of the bearing profile (8), so that rainwater can be collected on the curved plates (9) placed at an inclined angle and can be guided into the bearing profile (8) provided with upright edges, which in turn can collect water and guide it to a drain pipe. The modular skeleton system (1) according to claim 1, wherein between the uprights (2) can be placed substantially parallel to the long side (6) of the base (5) at the height of the bearing beams (3), beams (16) to be. The modular skeleton system (1) according to claim 2, wherein a ceiling (17) can be attached to and / or to the lower flange (3A, 16A) of the beams (3 and 16). The modular skeleton system (1) according to claim 3, wherein the ceiling (17) comprises planks, plastered panels, fiber boards, concrete fiber boards, plywood, drywall, a stretched cloth or a stretched fleece and / or any other suitable ceiling material. The modular skeleton system (1) according to claim 4, wherein the ceiling is provided with holes or flaps, which can be arranged, for example, near the facades. The modular skeleton system (1) according to one of claims 2 to 4, wherein the distance (A) is chosen such that the angle of inclination (a) of the curved plates is less than 45 degrees and preferably less than 35 degrees. The modular skeleton system (1) according to any one of the preceding claims, wherein a third set of bearing beams (21, 22) can be arranged at a distance (B) from the ground level (23) between the posts (2). The modular skeleton system (1) according to one of the preceding claims, wherein a set of purlins (25) can be arranged between the third set of bearing beams (21) substantially transversely of these bearing beams (21). The modular skeleton system (1) according to claim 8, wherein floor parts (26) can be applied to the purlins. The modular skeleton system (1) according to claim 9, wherein ventilation openings are provided in the floor parts (26). The modular skeleton system (1) according to any of the preceding claims, wherein the system (1) is built into a housing, the beams (21,22) and the first set of beams (3) supporting the first set / or walls, system walls, windows, doors and / or cladding are arranged between the third set of bearing beams and the second set of bearing beams (4). The modular skeleton system (1) according to one of the preceding claims, wherein the uprights (2) can be attached to an anchor (24) with a base plate (27). The modular skeleton system (1) according to any of the preceding claims, wherein substantially rectangular fly screens (28) between the beams (4.16) and the uprights (2) and substantially triangular fly screens (29) between the beams (3 ) the uprights (2) and the curved roof plates (9) can be fitted. A method of manufacturing a home comprising the following steps to be performed in any suitable order: a) Providing a modular skeleton system (1) according to any of claims 1 to 13; b) Placing a series of foundation elements (24); c) Placing the uprights (2) with the base plate (27) on the foundation elements (24) and bolting them, for example, through the middle of threaded ends arranged in the foundation elements; d) Placing the beams (3,4,16, 21, 22) between the posts (2); e) Attaching the supporting profile (8) provided with raised edges to the beams (3); f) Arranging purlins (25) between the beams (21); g) Laying floor parts (26) on the purlins (25); h) Installing walls, doors, and / or windows between the beams (3 and 21) and between the beams (16 and 22); i) Placing mosquito nets (28) between the top of beams (4) and the top of beams (16); j) Arranging insect screens (29) in the triangles formed by the top of the beams (3), the top of the uprights (2) and the raised edges (11) of the profile (8); k) Arranging a series of self-supporting curved plates (9) at an angle (ex) extending on a first side beyond the bearing surfaces (15) of the beams (4) and on a second side extending beyond projecting collars ( 12) of the bearing profiles (8) provided with raised edges; l) Installing the ceiling (17) between the lower flanges (3A and 16A); m) The possible placement of partitions with possibly doors and / or windows.