FI80497C - Method of producing an oblique and supporting corner as well as a corner element to produce an oblique corner in a trunk structure of a house made by building elements - Google Patents

Description

1 80497

A method for making an oblique and load-bearing corner and a corner element for making an oblique corner in the frame structure of a building made of building elements.

The invention relates to a method according to the preamble of claim 1 and a corner element according to the preamble of claim 4 for making an oblique corner in the frame structure of a building made of building elements.

In the building construction industry, the use of prefabricated building elements has steadily increased. The main reason is the cost of construction, i.e. curbing the rise in labor and capital costs in particular by shortening construction time.

The building element industry has so far produced building elements that can easily support rectangular construction; an example of this is FI publication 30127. This has also bound designers, as the implementation of other types of forms unreasonably increases costs. The implementation of oblique angles and asymmetrical shapes has therefore been rare and exceptional.

Where the construction has resulted in oblique corners, the construction has in practice been carried out in such a way that the straight building elements associated with the oblique corner are supported at the desired angle and apart from each other. A mold is then built into the corner, which is connected to the vertically supported straight building elements, and the interior of the mold is reinforced. Finally, the oblique corner is made by filling the mold with cast concrete11a. Such an approach, exemplified by U.S. Pat. 3357673 and DE-A-2063126, is slow and significantly increases costs. The costs are further increased by the fact that the corner still has to be finished with the normally needed surface cladding and thermal insulation. To achieve this, it is possible to use, for example, a non-load-bearing corner element according to FI patent application 860961, consisting of two gypsum boards and thermal insulation between them.

The primary object of the invention is to eliminate the disadvantages and weaknesses associated with traditional building construction, in particular the production of oblique corners of houses, and enables the construction of oblique corners of houses with a new method and corner element in order to substantially shorten the construction time.

These objects are achieved by the method and the corner element mentioned at the beginning for making an oblique corner in the frame structure of a building made of building elements, wherein - the method according to the invention the mating sides face each other, at a substantially constant size, at the distance required by the selected jointing method, e.g. with concrete elements preferably known per se, and the corner element according to the invention is characterized in that the corner element , wherein it has at least one side and two at an oblique angle to each other a connecting sides, from which the corner element is intended to be connected by a desired connecting method, e.g. by sealing, to the mating sides of said two elements.

In a preferred embodiment of the corner element according to the invention, the connecting side of the corner element and the mating side of the second building element to be connected thereto are parallel and perpendicular to the side of the corner element or, if the corner element is curved, intersect between this curved side and the connecting side. with the edge of the corner element, the tangent of the curved side passing through. In this case, the connecting sides of the corner element are at an angle to each other, which directly determines the angular deviation of the other building elements connected to it at an angle to each other and is the interior complementary angle between the other building elements to be connected to the corner element.

According to a preferred embodiment of the invention

II

3 With the method 80497, the wall element is first placed in its final position and supported vertically. An oblique corner element is then placed and supported next to it. A second wall element is then placed and supported on one side of the corner element. Thus, by selecting the angle between the connecting sides of the corner element, the magnitude of the mutual angular deviation of the wall elements associated with the corner element is determined.

Among the most significant advantages of the invention, it can be mentioned that multifaceted construction at oblique angles can now be carried out without formwork, reinforcement and casting work on the construction site. This shortens working hours and lowers costs. In addition, it should be noted that the elements may already have the final surface cladding ready, which further reduces the proportion of work required on site. It can also be stated that the construction method according to the invention is also excellently suitable for the so-called pilarirunkoraken-tamiseen. In this case, the corner element according to the invention forms a corner pillar which is made in the shape of a desired oblique angle. Another advantage of the invention is that not only at the corners of the walls, the construction method according to the invention can also be applied to the connection between the roof and the wall.

The invention will now be described, by way of example, with reference to some preferred embodiments thereof, with reference to the accompanying drawings, in which Figure 1 schematically shows a house made of building elements according to the invention, Figure 2 shows in more detail a part of of the corner element, Fig. 4 shows a cross-section of a corner element according to another preferred embodiment of the invention, Fig. 5 shows a cross-section of a corner element according to a third preferred embodiment of the invention. and Figure 6 shows a cross-section of a corner element according to a fourth preferred embodiment of the invention

The building according to Fig. 1 and the part of the building shown in Fig. 2 are assembled as already tentatively stated above, so that first one wall building element 1 is placed in its final position on the construction site and supported vertically. Then, next to the wall building element 1, at the end of the gap 2 required by the fastening method, an oblique or curved corner element 3 is placed and supported vertically, its first joint side 5 being aligned with the joint side 4 of the wall element 1. Then, on the other side of the corner element 3, the next wall element 1 is placed and supported vertically at the distance 2 required by the fastening method, at an angle determined by the corner element 3, whereby its connecting side 4 is aligned with the second connecting side 6 of the corner element 3. This is continued until the building elements 1 and 3 of the entire layer have been supported in place and finally the building elements 1 and 3 are connected to each other by a selected fastening method, e.g. by casting.

Alternatively, the straight wall elements 1 of the building, room, etc. to be built are placed and supported in the desired positions with respect to each other at a distance from the corner element 3 and the distance 2 required by the selected connection method. Then, suitably shaped corner elements 3 are arranged between them, and finally all the building elements 1,3 arranged in place are connected to one another by a selected fastening method.

According to a preferred embodiment of the invention, shown in Fig. 3, in each building element 1,3 the connecting side 4,5,6 is a planar surface and forms a rectangle with a straight part, preferably a planar surface, of the side side 7,8 bounding the connecting side of the corner element. In this case, the angle A between the connecting sides 5 and 6 of the corner element 3 with six longitudinal edges 9 corresponds to and / or directly determines the angular deviation B of the straight building elements 1 to be connected to it at an angle.

As can be seen from Fig. 4, which shows another preferred embodiment of the invention, the corner element 3 has four longitudinal edges 9 and the connecting sides 5 and 6 of the corner element 3 are arranged to merge at substantially one longitudinal edge of the corner element, with an angle A between the building. In this way, the dimensions of the corner element can be kept as small as possible.

In this second preferred embodiment of the invention, the connecting sides 5 and 6 are most preferably at right angles to the straight part of the side side 7, preferably the planar surface, outside the angle to be formed.

It is not necessary for the operation of the invention that the connecting sides 5 and 6 of the corner element 3 are, as planar surfaces, most preferably at right angles to the side side 7. In particular, in order to increase the mechanical load resistance of the joint, it is preferable that both the joint side 5 or 6 of the corner element 3 and the counter-joint side 4 of the straight building element 1 have a shaped surface, the imaginary planar surfaces passing through the shaped surfaces 5 and 6 intersecting at each other. the wall element 1 and the corner element 3 are shaped to correspond to each other, so that the space 2 required by the connection method chosen for each location remains in place after alignment and support, and so that no vertical or horizontal alignment installation is required but elements 1 and 3 can be installed; simply put in place. Figure 5 shows a cross-section of such a corner element 3 according to a third preferred embodiment of the invention, and in this third preferred embodiment the corner element 3 has six longitudinal edges 9 and the profile of the shape surface of each connecting side 5,6 is a broken line. In this connection, however, it should be noted that the profile of the shaped surface can be of another type, e.g. an arc, a wavy line, a tooth line or the like.

As can be seen from Fig. 6, which shows a fourth preferred embodiment of the invention, the corner element 3 is curved and comprises four longitudinal edges 9 and curved side sides 7 and 8 bounded by the longitudinal edges 9. in the preferred embodiment the connecting sides 5 and 6 are at right angles to the tangents of the curved side sides 7 and 8 passing through the longitudinal edges 9 and form an angle A between them corresponding to or directly determining the angular deviation B between the other building elements 1 6 8G497 to be connected to the corner element 3.

From the point of view of practical element construction, it is advantageous for the corner elements 3 to be made of constant dimensions so that the angle A between their connecting sides is constant, most preferably to cover an angle range between 0 ° <A <90 ° or 90 ° <A ^ 105 °. In this case, it is possible to build polygonal, even round, towers, pillars and similar structures using the corner elements 3 alone.

The invention has been described above by way of example only with the aid of some of its preferred embodiments and embodiments. This, of course, is not intended to limit the invention and, as will be apparent to those skilled in the art, the invention may be significantly varied within the scope of the appended claims. In particular, it should be emphasized that the shape of the side surface 7 or 8 of the corner element in particular can be chosen quite freely, e.g. multifaceted, whereby the number of longitudinal edges of the corner element increases or decreases and the aesthetic appearance of the corner element can be changed. It should also be noted that the corner elements can be manufactured using the most suitable working method in each case, e.g. plastics, metals, wood, concrete, reinforced concrete, aerated concrete or similar load-bearing materials, and that thermal insulation can be placed inside and / or outside the corner elements.

Il

Claims (8)

A method for making an oblique and supporting corner in a frame structure of a building made of building elements, characterized in that a load-bearing corner element (3) belonging to the building frame elements is arranged between the corner-related elements (1) so that said elements (1,3) the counter-joining sides (4,5,6) face each other, at a distance (2) from each other required by a substantially constant-sized, selected joint method, e.g. by casting with concrete elements, preferably known per se. Method according to claim 1, characterized in that first the first wall element (1) is placed in its final position and supported, that next to the first wall element (1) an oblique corner element (3) is placed and supported in its final position, and that the corner element (3) 3) on the other side, a second wall element (1) is placed and supported in its final position, whereby the choice of the angle (A) between the connecting sides (5,6) of the corner element (3) determines the mutual angular deviation (B) of the wall elements (1) associated with the corner element (3). Method according to Claim 1, characterized in that the first and second wall elements (1) are initially placed and supported in their final position relative to one another in the desired position, and that a corner element (3) is then arranged between the wall elements (1). ) is selected so that its connecting sides (5, 6) are aligned and substantially parallel to the connecting sides (4) of the wall elements. A corner element for making an oblique angle to the frame structure of a building made of building elements, characterized in that the corner element (3) is a load-bearing frame element which is part of the building frame structure and determines the mutual angular deviation (B) of the two associated elements (1). 80497 side side (7) and two connecting sides (5,6) at an oblique angle (A) to each other, of which the corner element (3) is intended to be connected by a desired connection method, e.g. seam, to the mating sides (4) of said two elements (1) . Corner element according to Claim 4, characterized in that each connecting side of the corner element (3) or the imaginary plane passing therethrough is substantially perpendicular to the part of the straight surface of the side element (7) of the corner element (3) or its intended extension, the corner element (3) 5, 6) are at an oblique angle (A) relative to each other, which determines the mutual angular deviation (B) of the elements (1) connected to the corner element (3), the magnitude of which is the complement angle of the angle inside the corner between said two elements (1). Corner element according to Claim 4, characterized in that each connecting side of the corner element (3) or the imaginary plane passing therethrough is substantially perpendicular to the curved side side (7) of the corner element (3) running the connecting side (5, 6) and the side side (7). 8), the connecting sides (5, 6) of the corner element (3) being at an oblique angle (A) to each other, which determines the mutual angular deviation (B) of said two elements (1) associated with the corner element (3), and which is the complement angle of the angle inside the corner between the two elements (1). Corner element according to Claim 5 or 6, characterized in that the connecting sides (5, 6) of the corner element (3) are planar surfaces and in that the corner element (3) has at least three, preferably four, longitudinal edges (9). 7 80497 Corner element according to claim 5 or 6, characterized in that the connecting sides (5, 6) of the corner element (3) are shaped surfaces, said shaped surface profile being a broken line, arc, wavy line, tooth line or the like, and that the corner element (3) has at least three, preferably four, longitudinal edges (9). Il 9 80497