SE520873C2 - Disc shaped building element with connecting members consisting of slats in a zigzag pattern - Google Patents

Abstract

The present invention relates to a plateformed building element (1), intended for the construction of floor structures and/or walls and consists of wood or some other fibrous material with members (2) connecting inner and outer sides (5, 6) positioned at a mutual distance (A). Said connecting members are formed from plateformed lamellae (2), distributed essentially along the whole surface range of the intended building element. They extend incliningly and/or curved in zigzag patterns and are distributed along said building element (1) in pairs (2, 2) forming parallel channels (51) therein.

Description

520,873 total costs for a more efficient production in the factory and a better utilization of the material's load-bearing capacity and which also gives the building element low dead weight.

Said object is achieved by means of a disc-shaped building element which is mainly characterized in that the rule-forming slats are fastened to stripes and / or beams extending across them with nails or screws, that the fastening joint is formed by paired stirrup-shaped receiving parts for beams arranged in adjustable sets. angle to each other and that the regulating slats are received with their longitudinal edges in grooves of the receiving parts.

The invention is described below as a number of preferred embodiments with reference to the accompanying drawings, in which Fig. 1 shows a perspective view of a disc-shaped building element according to the invention seen obliquely from above, Figs. 1A-1C show different embodiments of connections of building element parts, Fig. 2 shows a second example of a building element, Fig. 2A shows the internal connections of said second element, Fig. 3 shows a third example of a building element, Fig. 3A shows the internal connections of said third element, Fig. 4 shows a fourth example of a building element, Fig. 4A shows the internal connections of said fourth example, Fig. 5 shows a fifth example of a building element, Fig. 5A shows the internal connections of said fifth element, Fig. 6 shows a sixth example of a building element according to the invention, and 520 873 Figs. 6A-6C shows connections for said sixth building element.

Known embodiments comprise building elements which are formed by boards on opposite sides of inclined or curved channel-forming slats and which slats and boards are fastened together by gluing.

The advantage of using beams on at least one side of the building element instead of slabs is that the building element is mainly formed only by the centrally located slats which are arranged to extend at an angle to each other and in interconnected position be able to absorb said building element substantially the entire load.

Connection of building elements to lateral beams takes place according to the present invention by means of stirrup-shaped angled fastening connections which comprise paired stirrup-shaped receiving parts for beams, for example as shown in Fig. 6.

General description of the building element and its use âiïL The manufacture of the building elements must be made as standardized as possible with a width of 1.20 m or 2.40 m, but the length may vary due to its construction method. It is also possible to splice the building elements in its longitudinal direction.

The building element proposed according to the invention for this purpose is characterized in the first place by the slats being mounted in e.g. oblique angle as one or more sine curves that absorb the tensile and compressive forces with a zero point in the middle of the building elements. The forces will thereby interact with the outer shell in an effective manner.

When building floors and / or rule walls intended for building elements of wood or other fibrous material, the core of the floor or wall element is designed as a trigonometric design so that the load-bearing capacity increases exceptionally in cooperation with the design of the outer shell. The forces interact like a sine curve. This is held together with joists, boards or board material transversely at the top and at the bottom. At the breaking points, the material is fixed together. It forms long triangular channels along the joists or beams both in the lower and upper edge.

These walls and floors are intended to be manufactured in elements in the factory to keep manufacturing costs down.

It costs a lot in the start-up phase with the construction of production lines, but can provide a lot for the future where you can keep production costs down.

The properties of the wall and floor meet many requirements. The strength of the elements in all stages is unique. Good tightness is obtained, thanks to the composition of the joists and beams.

There will be no cold bridges and the fire protection is also good thanks to the tightness. It must burn in a lot of material before it burns through. The damping ability of sound is good because the sound vibrations wander away towards the sloping surfaces.

In floors and wall systems Instead of bars in walls being placed perpendicular to the outer and inner sides of sills or hammer bands, the bars are now set obliquely or are curved towards each other with a connection in the short sides of the bars to the outer and inner edge of the wall. In this way, a zigzag pattern is achieved in the wall system which gives the wall many good properties, e.g. carrying capacity, sound, fire, tightness and very good stability at all stages.

The same applies to floors. There you place the beams (beam) at an angle to each other, but at the upper end of the beams they are assembled with each other. This also applies to the lower ends. The assembly can be done with sheet metal shoes that are specially made for the purpose. You can also use boards, joists or boards that act as cohesion in the building element.

The present invention relates to a cell-divided trigonometric building element in which the cells are held together in the upper and lower layers with sheet material or the like.

More particularly, the invention relates to such a building element of the type comprising a plurality of cells, of equal appearance, adjacent and mounted to each other with glue or the like. The sloping slats form a number of identical cells in the building element. There are a large number of different cell systems where its appearance depends on the design of the slats. The patterns of the different cells form longitudinal channels in the longitudinal direction of the building element. Each of the different cell systems has different properties, but it is the most cost-effective cell system in relation to the best properties that determines the manufacturing system, which must be as industrialized as possible. The material of the building element in over- and under-failed can be different, e.g. board material, boards or joists of wood or other fibrous material mounted with glue or the like.

Drawers can also be used in failure of the elements to increase the load-bearing capacity of the building elements. These drawbars can be used to clamp the building elements together into large continuous floors during assembly at the construction site.

Prefabricated building elements of the type mentioned are primarily used as load-bearing floors and roof elements in the construction of single-family houses, apartment buildings, outbuildings and industrial premises, etc. However, they can also be used for other purposes, for example as load-bearing wall elements.

Detailed description of the invention: The invention further describes below with reference to the accompanying drawings in which Fig. 1 shows a perspective view of a disc-shaped cell-shaped building element 1 according to a first exemplary embodiment of the invention with triangular slanted slats 2 assembled for mounting in upper edge 3 and failed 4. On the upper side 3 of the building elements 1, materials of various kinds were used, such as boards 5 of boards, joists or iron bars. On the underside 4 of the building element 1 shown, tie rods 6 or joists are mounted.

Figs. 1A-1C show in enlarged end views which describe the design of the slats 2 when mounting them. All slats 2 are identical elements even when mounted between the elements and there is a large variation in designs. The prerequisite is to achieve as large an area of the joint as possible.

Therefore, a number of different variants have been chosen: 1A shows tooth design 1B shows tongue design and 1C shows round bar design. All designs are mounted with glue, screw, nail or similar.

Fig. 2 shows a perspective view of a disc-shaped cell-forming building element 101 according to an exemplary embodiment of the invention with triangular inclined slats 102 which are assembled for mounting in upper edge 103 and lower edge 104. The slats 102 are constructed with triangular bars 107, 108 which has milled grooves 109 in which inclined disc-shaped slats 102 are mounted between the triangular joists according to Fig. 2. The upper side of the building element can be made of board material 105, boards, joists or iron bars 106. The same applies to the underside 104.

Fig. 2A shows an enlargement of two disc-shaped building elements 101 when assembled laterally. The building elements are not fully assembled to show that the spring (guide strip) 111 is mounted in a longitudinal groove 110 in a divided triangular rule 108 in each building element 101. The procedure forms an equally large triangular rule when assembling the building elements 51. The building element 101 is made up of triangular bars 107 which are grooved 109 for mounting disc-shaped slats 102 which are inclined. Between the bars in the outer edges of the building element 101, the triangular bars 108 are provided with an extra groove 110 for receiving a longitudinal spring 111 in the assembly of the building elements 101.

Fig. 3 shows a perspective view of a further building element 201 according to an exemplary embodiment of the invention. The design is based on a disc that is shaped so that it is formed as a wavy sine curve and thus cells are built together with an outer layer on the upper and lower side of the building element. The upper side of the building element can be made with board material 205, boards, joists or iron bars 206. The same applies to the lower side 204.

Fig. 3A shows a small part of the enlargement of two building elements 201 during assembly. They are not fully assembled to show that the spring (guide strip) 211 is mounted in a guide groove 209 and which holds the elements 201, 201 together.

Fig. 4 shows a perspective view of a cell-shaped building element 301 according to an exemplary embodiment of the invention with a geometric construction which forms a cell system with slats. Said building elements form two wavy sine curves which absorb compressive and tensile forces in the entire cell system.

The oblique cells 302 forming regular 8-corner are effective in this embodiment. In the upper and lower part of the building element, board material 305, 306, boards, joists or iron bars are mounted.

Fig. 4 A shows an enlargement of two building elements during assembly. The building elements are not fully assembled to show that the function of the springs (guide strips) is mounted in grooves in the upper and lower part of the building element.

Fig. 5 shows a perspective view of a cell-shaped building element 401 according to an exemplary embodiment of the invention with a geometric construction which forms a cell system with circular slats. Said building elements form two wavy sine curves that absorb compressive and tensile forces in the entire cell system. The inclined arcuate slats 402 form with the surface layer 405; 406 a strong building element that absorbs large loads. In the upper and lower part of the building element, board material, boards, joists or iron bars are mounted.

Fig. 5 A shows an enlargement of two building elements during assembly. The building elements are not completely assembled to show that the springs (guide strip) are mounted in grooves in the upper and lower part of the building element. Insulating material I can be received in cavity 450 in said building element 401 and also inside the cells 451.

Fig. 6 shows an example of a floor element 501 which is built up of a plurality of elongate oblique disc-shaped slats 502. Above and below said slats 502 are attached fixed transverse floor joists 505 and ceiling joists 506, respectively.

At the bottom of the floor, fastening can take place with the help of tie rods (not shown) in order to be able to absorb greater loads.

Fastening of the floor joists 505 and the ceiling joists 506 can take place by means of coupling members 512, 513 in the form of U-shaped assembly irons and angled mounting plates.

Detailed description of the invention The invention thus more particularly relates to a disc-shaped building element 1; 101, 201, 301, 401, 501 which are intended for the construction of floors and / or walls. It consists of wood or other fibrous material with between two mutually spaced outer and inner sides 5; 105; 205; 305; 405; 505 and 6, respectively; 106; 206; 306; 406; 506 connecting means 2; 102; 202; 302; 402; 502.

The connecting means are formed by disc-shaped slats which are distributed along the substantially entire entire surface of the intended building element extending inclined and / or curved in a zigzag pattern and are distributed along the said formed building element in pairs forming parallel channels 51; 151; 251; 351; 451; 551.

The said connecting means are connected to each other towards the inside of the respective pair-wise sides of the building element, which are preferably plate-shaped. Connections between the slats 2; 102; 202; 302; 402; 502 may be formed by cooperating mold recesses 55, 56 and / or by strip-shaped insert rods 57, 58 which are arranged to be received in gutter-shaped recesses 59, 60; 61, 62 in said rule-forming slats 2 as shown in Figs. 1A-1C.

The said regularly arranged slats 2; 102; 302; 402; 502 are connected to each other as well as to the said pair- Show surface disks. In the embodiment according to Fig. 2, the forming lamellae 102 are received with their opposite edges in grooves 109 of strip-shaped coupling pieces 107, 108. Said coupling pieces are formed with a triangular cross-sectional shape in the preferred embodiment shown and are fastened by adhesive joints, screw or nail joints. to adjacent connecting discs etc 105; 106. The said grooves 109 are arranged, for example, so that they extend in pairs perpendicular to each other.

The building element 201 shown in Fig. 3 has connecting means 202 which form a wavy longitudinal partition wall in the formed building element 201.

According to embodiments shown in Figs. 4 and 5, they are connectors 302; 402, which are arranged on the building elements 301 thus created; 401 gutter-shaped, seen in the surface extent of the building element and running parallel in relation to each other. In interconnected mode, they form channels 351; 451 with round or polygonal cross-sectional profile. 520 873 10 The lamella-forming slats are attached to the strips and / or beams which extend across said slats by means of glue, nails or screws.

Figs. 6-6C show how such nail connections 512 are formed by paired bracket-shaped receiving parts 512A, 512B for beams 505, 506 which are arranged set or adjustable at an angle to each other with its receiving parts 512A, 512B. A pivot joint 513 in the form of a bolt 513A and nut 513B may be provided to connect the two beam receiving portions 5112A, 512B which are adjustable relative to each other. By turning one of the receiving parts 512A, it is adjusted in height and at an angle relative to the other connecting receiving part 512B.

The main idea of the building system The present wall and floor system has a technical height and thus the right economic properties. With new products with new thinking such as this building frame that will be supplemented with other working methods, competition will be better for wood and increase the value of wood with great potential.

According to calculations, the floor system has a load-bearing capacity in fracture lane conditions and dynamic rigidity against fluctuations in working lane condition, and which is a good measure of overcapacity in both cases.

To skew the beams and to bring them together in the upper and lower ones means that great opportunities are opened up for the future of wooden constructions. The system shows the incredible strength of wood in its interaction in a cell system. The flooring with this dead weight has a rigidity and load-bearing capacity that surpasses other flooring 520 873 ll in this flooring system, the entire structure of the flooring from lower to upper edge is used as load-bearing properties that are easy to make installations in upper and lower. the sound has difficulty penetrating the sloping beams the same applies to fire, if you insulate the floor well then the fire has difficulty penetrating the beams the floors are very cost effective the possibility to increase the capacity of the floor increases by raising the zigzag pattern which does not affect the dead weight significantly. It is also possible to make a denser placement of studs in over- and under-recognized and to use sheet material the building elements are easy to splice in length and width the building elements must be manufactured in widths of 2, 40 m and in lengths of loose if necessary. Can also be manufactured in other lengths the floor system can be used for roof elements where attics can be placed directly on the roof element and thus the entire attic space can be used as the floor height of the floor is less than other floors due to the construction the floor is easy to mount the wall element is mounted standing in the whole house up to the roof without any horizontal timber the floor rests hanging on the load-bearing wall and is anchored in the wall with clamps The building elements are easy to insulate in the length of the triangular channels with profiled insulation mounted in descending lengths between the joists mounted perpendicular to the triangular the ducts insulation is also easy to assemble the floor elements can be assembled together on the construction site in a fixture where the suspended ceilings are mounted in an ergonomic way.

The floor elements are then hoisted in place 0 The wall elements can also be mounted in place lying along their entire length and then hoisted in place 0 the building system in parts or in its entirety can also be used for many different other constructions e.g. pillars, noise plank, roof elements in hall buildings, stairwells, elevator shafts etc.

The invention is of course not limited to the embodiments described above and shown in the accompanying drawings. Modifications are possible, in particular as regards the nature of the various parts, or by the use of equivalent techniques, without departing from the scope of the invention as defined in the claims.

Claims (7)

fi? .. n. . .. _,., 5 8 3 - ...,. i,. f.,. i,,: U L.. . ..,,. 6 V.. ., - 1 1. , _ '' '/ 3 P a t e n t k r a v Disc-shaped building element (1; 101; 201; 301; 401; 501) for the construction of floors and / or walls and consisting of wood or other fibrous material with spaced apart outer and inner sides (A) (5; 105; 205; 305; 405; 505 and 6; 106; 206; 306; 406; 506, respectively) connecting means (2; 102; 202; 302; 402; 502), and that the connecting means are formed by disc-shaped rule-forming lamellae which are distributed along the substantially entire surface extent of the intended building element extends inclined and / or curved in a zigzag pattern and distributed along the said formed building element and in pairs forming parallel channels (51; 151; 251; 351; 451; 551) therein, characterized in that the rule-forming slats are fastened transversely extending straps and / or beams (6) with nails or screws, that the fastening joint (512) is formed by paired bracket-shaped receiving parts (512A, 512B) for beams arranged at an angle or adjustable at an angle to each other and are received with their longitudinal edges in grooves of the receiving parts. Disc-shaped building element according to claim 1, characterized in that the connecting means (2; 102; 202; 302; 402; 502) are interconnected with each other towards the inside of the respective pair-like surfaces of the building element, which are preferably plate-shaped. Sheet-shaped building element according to claim 2, characterized in that connections are formed by mold recesses (55, 56) and / or by strip-shaped insert rods (57, 58) which are arranged to be received in gutter-shaped recesses (59-62) in said rule-forming slats (2). 520 873 / Å / Sheet-shaped building element according to one of Claims 2 to 3, characterized in that the rule-forming slats are connected to one another as well as to the surface boards. Disc-shaped building element according to Claim 1, characterized in that the coupling pieces (107, 108) have a triangular shape and with grooves (109) which extend perpendicularly in relation to one another. Disc-shaped building element according to one of the preceding claims, characterized in that the connecting means are formed by a wavy partition wall (202) in the formed building element (201). Disc-shaped building element according to one of Claims 1 to 5, characterized in that the connecting means (302; 402) are gutter-shaped seen in the surface extent of the building element and that in the interconnected position they form round or polygonal channels (351; 451).