NO773053L - FOUNDATION AND BASEMENT FOR HOUSES. - Google Patents

Description

The invention relates to a foundation and a basement for a house, more specifically a foundation comprising prefabricated elements for a house resting on pillars, as well as a basement, likewise comprising prefabricated elements.

In the following, the invention shall be described in more detail with reference to the drawings which show exemplary embodiments of a foundation and a basement according to the invention, and where fig. 1 shows a longitudinal section of a buried pillar, fig. 2 shows a longitudinal section of two-jointed foundation beams resting on and anchored to a pillar, fig. 3 is a perspective view of the upper end part of a foundation beam, fig. 4 and 5 are perspective views of the upper end part of a buried pillar, fig. 6 is a plan view of two jointed foundation beams resting on and anchored to one pillar, fig. 7 is a plan view of three interconnected foundation beams resting on and anchored to a pillar, fig. 8 and 9 show two design examples of filling soil up to a foundation according to the invention, fig. 10 shows a floor plan of a cellar according to the invention, fig. 11 shows a section along the line 11 - 11 in fig. 10, fig. 12 shows an embodiment of a box for soil and water pipes., fig. 13 is a perspective view of the above ground visible parts of a foundation and a basement according to the invention, and fig. 14 shows a vertical section through a plastic sheet used when filling soil up to a foundation.

The house foundation according to the invention is intended to be used in connection with pillars, e.g. of the type described in Norwegian patent no. 115 378 and shown in fig. 1. This pillar 1 comprises an outer, tubular formwork 2 and a lower, inverted funnel-shaped sole formwork 3, which formwork is filled with concrete 4. In the drawing, also shown is an upper, funnel-shaped, likewise with concrete, filled formwork 5, which is mainly only used when using pillar 1 as a pipe foundation etc.

The pillar used to support the foundation according to the invention therefore only includes the sole and that above it

located cylindrical part. The formwork is made of a material that does not bind to concrete, so that even if the surrounding soil mass freezes to the formwork and lifts it when it is lifted, the inner concrete core will remain at rest.

For anchoring the foundation to the pillar, its upper part is provided with an upwardly open, central hole 13 which extends a certain distance downwards in the longitudinal direction of the pillar, and which can be provided by inserting an elongated, slightly downwardly tapering core 6, 7 with a cylindrical or oval cross-section, in the concrete, which core is removed after the concrete has hardened.

On the pillars, concrete support beams with a length corresponding to the length of the house can be arranged as a base for its bottom rest. The beams can have a suitable cross-section for this purpose, e.g. a rectangular cross-section with greater height than width, as shown in fig. 3. In order to avoid excessively long and heavy beams, however, it is often advantageous to join several

shorter beams. Adjacent end portions of beams to be joined are preferably arranged resting on their respective pillars.

According to the invention, the tensile loads occurring in the joint can e.g. is taken up by a rebar 9 with an inverted U shape. In order to receive this rebar 9, a central recess 10 designed as an open channel is arranged in the upper surface ay of the end part of each beam 8, 19, which runs horizontally in the longitudinal direction of the beam and extends from the end of the beam a distance corresponding to the inverted U -shaped rebar 9.half the width, and which ends in a vertical recess whose height is somewhat greater than the height of the rebar 9. The height and width of the rebar and the recess are determined by the loads that are expected to occur in such a joint connection.

In the end surfaces of the end parts of the beams 8, 19, a central, vertical recess 12 can be arranged which,

when these end surfaces are brought into contact with each other, form a through hole. which escapes, with the hole 13 arranged in the upper part of the pillar 1.

During splicing, the end surfaces of two beams 8, 19, which rest with adjacent end portions on one and the same pillar 1, are first brought into contact with each other. Next, a rod-shaped anchoring iron 11 whose length is somewhat less than the sum of the depth of the hole 13 and the height of the beam 8, 19" is inserted into the flush holes 13, 14, after which the inverted U-shaped reinforcing iron 9 is placed in the recesses 10 in the end parts of the beams 8, 19, after which the holes 13, 14 and the recesses 10 are filled with concrete.

The bottom sleeper of the house can be anchored in the beams by inserting a short, vertical iron rod 20 into the recess 10

above the anchoring iron 11. Alternatively, for example, the iron brace 9 can have a vertically extending hole at its middle part, and the anchoring iron li be so long that, after insertion in this hole and resting against the bottom of the hole 13, an upper part protrudes above the beams 8, 19 upper surface. The iron rod 20, respectively the upper part of the anchoring iron 11 can be arranged for insertion into a vertically arranged hole in the house's bottom sleeper and further be provided with threads to secure the connection of the bottom sleeper with the beams 8, 19 by means of a washer and a nut.

In a similar way, two jointed beams 8, 19 can be connected at the joint with a further one standing vertically on them. beam 16 provided with recesses as for beams 8, 19, as shown in fig. 7. In this case, the hole 13 of the pillar 1 has an oval cross-section and the jointed beams 8, 19 are not placed centrally above the pillar, but slightly offset, so that the beam 16 with its end part can also rest on the pillar 1. Apart from the fact that the beams 8 are slightly offset, the anchoring and joining of the beams 8, 19 is carried out in the same way as previously described. The beam 16 is anchored to the pillar by means of a U-shaped anchoring iron 17 whose width is approximately equal to the half-width of the above-mentioned U-shaped reinforcing iron 9 and the length of one leg of which

is equal to the 9 leg length of the rebar. The length of anchorage

the other leg of the iron 17 is somewhat smaller than the sum of the depth of the hole 13 and the height of the beam 16.

When the beam 16 is connected to the pillar 1, the beam 16 is brought with its end surface into contact with one side of the joined end part of the beams 8, 19. due to the oval cross-section of the hole 13 and the displacement of the beams 8, an area of the opening of the hole 13 will not be covered .of these and also remain uncovered by the beam 16 as a result of the recess 12. The anchoring iron 17 is placed in the hole 13 and the recesses 10,

12, after which the hole and recesses are filled with concrete.

In the same way as the beam 16 is attached to

pillar 1, two perpendicular beams can also be anchored to an underlying pillar and form a corner for a foundation. The anchoring iron 17 is then used for both beams and the connection will have an appearance as shown in fig. 7 with e.g. one beam 19 removed..

To avoid that the soil beneath the beams touches the underside of the beams and raises them. these at tail lift, the upper end of the pillars 1 is arranged somewhat above the surrounding ground level. For this reason, it is important that the opening between the underside of the beams 8, 16, 19 and the ground is not sealed when filling with soil or the like up to the foundation. To prevent such a seal, prefabricated plastic sheets 18 with the same thickness as normal foundation wall sheets can be arranged around the foundation and e.g. provided with embossed lines which facilitate the folding of the plate along the beams 8, 16, as shown in fig. 8 and along a wooden panel cladding at the end of the space under a house limited by the foundation beams 8, 16, as shown in fig. 9.

The invention also includes a basement made from prefabricated elements. In the one in fig. 10 and 11, the basement 30 is built from a lower element 31 comprising a floor and a low, thicker ring-wall-like wall portion produced in one piece with this, which projects vertically up at the floor's outer limits, seen from above. The upper surface of this wall section is provided with an elevated, central section 35.

On this lower element 31 is placed a

element 32 in the form of a short, square tube with a wall thickness and cross-section corresponding to the lower element 31's wall portion. The lower surface of the element 32 is provided with a central recess 36 for engagement and tight connection with the elevated part 35 of the element 31, which engagement ensures centering of the element 32 on the element 31. Above the element 32, there are similarly arranged two further elements 33 and 34. The heights of the elements are preferably chosen so large that the basement floor can be placed below the level at which the ground freezes in winter, while the upper element 34 is above. flat is approximately at the same level as the lowest floor in the building above.

The two upper elements 33, 34 can e.g. be made of an insulating material, e.g. Leca, while they. two lower

■elements 31,. 32 can be cast from concrete. The sealing between the elements can be done as too tight basins in concrete. All elements can also have reinforcement as well as cavities etc. to reduce the weight of the elements.

Around the basement, a foundation wall plate can be arranged, so that the surrounding, moist soil does not freeze to the elements and, in the event of heaving, raise them.

The external dimensions of the elements can be adapted to the Road Directorate's requirements for transport on Norwegian roads.

The elements can be produced split, comprising, for example, only three walls, so that these form a U, seen from above, whereby the free end parts of the walls of two such elements can be connected in the same way as the previously described foundation braces '8, 19 and form a basement element corresponding to one of the elements 31, 32, 33, 34, but with a rectangular shape, which enables the construction of a basement with twice the floor area while retaining the above-mentioned external dimensions for the element parts.

In the same way, the elements can be produced split, comprising only two walls, which enables the construction of a cellar with a fourfold gold area in relation to a cellar built from the elements 31 , 32 , 33 ,. 34 .

On.fig. 11 shows how soil and water pipes can be brought frost-free into a house without a basement by means of a frost-free depth buried, e.g. box 40 made of pressure-impregnated materials, the upper end of which projects up to a level between the underside of the overlying floor and the ground. An upper part of the box 40 is telescopically taken up by a downward-pulling box 41 connected to the underside of the floor to accommodate possible mutual movement of the box 40 in relation to the box 41.

Fig. 13 shows a fully assembled foundation and a finished basement before construction of a house has begun.

Claims (9)

1. System for the construction of foundations and basements for houses, characterized by the fact that it comprises a number of prefabricated concrete foundation beams whose adjacent, firmly connected ends each rest on a pillar rising above ground level, the lower end of which is located at a frost-free depth, so that the pillar and the foundation beams cannot be lifted by telelift, and with which pillar the beam ends are firmly connected, as there are plastic plates that prevent the fill material from freezing until the foundation beams have been filled and when telelift raises these, as well as a prefabricated basement arranged between the foundation beams, whose floor is also located - at a frost-free depth and is surrounded by a plastic sheet that prevents freezing of surrounding soil masses to the basement walls and lifting of the basement by telehive. 2. System according to claim 1, characterized in that the adjacent ends of two flush foundation beams (8, 19) are interconnected by means of an inverted U-shaped rebar (9), and that an open channel is arranged to receive this designed, central recess (10) in the upper part of the end part of each beam (8, 19), which channel (10) extends from the beam end horizontally in the longitudinal direction of the beam (8, 19) a distance corresponding to the inverted U-shaped half the width of the rebar (9), and which channel (10) ends in a vertical depression whose height is somewhat greater than the height of the rebar (9), which after placement in the channel (10) of the two beams (8, 19) is firmly connected with these by filling the channel (10) with concrete. 3. System according to claim 1 or 2, characterized in that the upper part of the pillar (1) is provided with a upwardly open, central hole (13) which extends a certain distance downwards in the pillar from its upper end face, in the longitudinal direction of the pillar, and that a central, vertically extending recess (12) is formed in the end faces of the beams (8, 19) which, when these end surfaces are brought into contact with each other over the middle part of the pillar (1), form a through hole which is flush with the hole (13) formed in the upper part of the pillar (1), since in this hole (13) and in the aforementioned , through holes formed by the beams, a rebar is arranged which, by pouring concrete into the holes, connects the beams -(8, 19) firmly to the pillar (1). 4. System according to claim 1 or 2, characterized in that a further beam (16) is arranged which is perpendicular to the two beams (8, 19) and one end of which abuts the adjacent ends of the two beams (8, 19), and which one end, like the other two mentioned beam ends, rests on the pillar (1) and is designed with a channel (10) and a recess (12), the further beam (16) being connected to the pillar and the two aligned beams by means of an inverted U-shaped rebar (17) whose width is approximately equal to half the width of the first rebar (9) and whose length of one leg is equal to the leg length of this rebar (9), while the length of the other leg is slightly less than the sum of the depth of the pillar hole (13) and the height of the beam (16), which other rebar (17), after placement in the channel (10) of the beam (16) and the hole (13) of the pillar, connects the beam (16) with the pillar (1) by casting with concrete. 5. System according to claim 1, characterized in that the basement comprises a lower element (31) with a floor and a ring wall-like, made in one piece with this, wall section projecting up from the outer edges of the floor with an upper connecting surface and a number of further wall elements (32, 33, 34) with upper and lower connecting surfaces and shaped like short tubes with wall thickness and cross-section corresponding to the lower element (31) ring wall-like wall part, which further wall elements can be arranged one above the other on the lower element (31) and form an upward extension of this wall part, the upper connecting surface of an underlying element being brought into contact with the lower connecting surface of an overlying element. 6. System according to claim 5, characterized in that the basement's lower element (31) is divided according to a plane that is perpendicular to the floor plane and comprises at least two sections with a floor part and one in one piece with this manufactured wall part, which sections after assembly form the lower element (31), and the further wall elements (32, 33, 34) in a similar way comprise at least two sections which, after assembly, form the further . wall elements. 7. System according to claim 5 or 6, characterized in that the upper connecting surface of the wall part and the wall elements (32, 33, 34) has a longitudinal, elevated central part and the lower connecting surfaces of the wall elements (32, 33, 34) have a complementary to the elevated part designed, longitudinal central depression. 8. System according to claims 5-7, characterized in that the basement comprises four elements (31, 32, 33, 34), of which the two bottom elements (31, 32) are made of concrete and the other elements (33, 34) are made of a heat-insulating material. 9. System according to claims 6-8, characterized in that the sections of the lower element (31) and the further wall elements (32, 33, 34) are firmly connected to each other by means of channels formed in the elements and reinforcing bars cast in concrete.