FI60902C - AV LAETTBAERVERK FRAMSTAELLD BYGGNADSENHET - Google Patents

Description

F55r * 1 ΓΒΐ M1V ICUULUTUSJULKA.SU 6090 9 JSTa lBJ (11) utlAggningsskrift • C (45) Patent granted on 13 04 1982, (fiÄ2r Patent meddelat (51) K, .ik.Va.3 E »B 5/10 // EMO 2/40 FINLAND — FINLAND (21) P »t * nttlh» k «nHi * - Patwitaraeknlng 751336 (22) H * k« ml * pily | - Anseknlnpdag 06.05-75 '(23) Alkupilvi - Glltl | h * tsd * g 06.0 5 · 7 5 (41) Become public - Bllvlt offantllg 08.11.75

Patent and Registration Office .... .... , ,. ,,. „, -. . . - - (44) Date of signature and date of issue. -

Patents and Registration of Antiquities and Publications 31 · 12.8l (32) (33) (31) Ρ) 7 «Ι ·« Χ «uolkeui-Begird prlorltet 07. 05 -71 *

Sweden-Sverige (SE) 7 ^ / θ6θ66-6 (71) (72) Jens-Fredrik Larssen, Birger Jarlsgatan 62, S-ll ^ 29 Stockholm, Sweden-Sverige (SE) (7 ^) Berggren Oy Ab (5M Lightweight manufactured component - Av lättbärverk framställd byggnadsenhet

The present invention relates to a building component made of a plurality of lightweight dance elements, which is intended to be mounted horizontally between load-bearing points for loading from above.

U.S. Pat. . However, this element is intended to be fitted on top of the actual supports and cannot itself receive the said load. It is also clear that even when reinforced, gypsum does not have such strength properties that it would be suitable as a structural material for a load-bearing element.

The object of the present invention is to provide a load-bearing component made of a lightweight trap, wherein a lightweight trap in this context means a load-bearing element or cassette consisting of a thin plate base profile provided on one side with a cover layer of another and stiffer material. The base profile and the cover layer form a rigid unit in which both parts work together statically. The lightweight punch has high flexural strength with the top layer in the compression zone.

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The main features of the building component according to the invention appear from the appended claim 1.

The building components according to the invention can form a gable roof, a subfloor, a beam, walls, etc. Compared to conventional structures, the use of this light weight has numerous essential advantages. Thanks to the combination of the lightweight base profile and the cover layer, the cover layer acts not only as an upholstery material but also as a load carrier. While maintaining the load-bearing capacity and rigidity of the load, a lighter building element suitable for large spans is obtained, even with a lower material consumption than in the conventional construction method. The material of the cover layer can be freely chosen depending on the requirements set for the building component and the intended function. Lightweight traps can be made in running lengths, and trap manufacturing requires little investment. Finished, stackable base profiles and cover layers can possibly be delivered separately and assembled on site. This results in low transportation costs. In addition, cheaper insulation material can be used, and ventilation pipes, electrical wiring and electrical installation spaces, water pipes, etc. can be installed inside the light rails. All in all, the advantages mentioned provide an economical and easy-to-install light weight, which requires little material and is simple to manufacture, which is suitable for large spans and which can also be advantageously reused.

The invention will now be described in more detail with reference to the accompanying drawings. In the drawings, Figure 1 shows a cross-section of a lightweight building component according to the invention. Figure 2 shows a truncated view of three different embodiments of a lightweight base profile. Figures 3, 4 and 5 show three different possibilities for the embodiment of the refill cartridge profile, Figure 6 shows an embodiment of the locking profile of the light cutters and Figure 7 shows the curves related to the strength examination.

The building component according to the invention consists of interconnected light dams, two pieces 1 and 2 of which are shown in Fig. 1. Each light duct consists of a base profile 3 of thin sheet metal provided with a cover layer 4 of another material. The base profile may be made of a suitable sheet metal material such as steel or aluminum. and the cover layer 4 may be formed of a wood material such as plywood, fibreboard or particle board, it may also be formed of a plastic material, asbestos cement material, gypsum board or the like. The base profile 3 and the cover layer 4 are joined together as a statically cooperating unit by a seam 5 in the flanges 3a of the base profile. The seam 5 can be provided with a waterproof adhesive which creates a base seal between the base profile and the cover layer.

The base profile 3 can have any suitable appearance, and the base profile shown in Fig. 1 has inwardly turned, narrow flanges 3a against which the cover layer 4 is attached. Figure 2 shows three different embodiments of the base profile with the flanges turned outwards. The embodiments shown are illustrative only, and a large number of other profile shapes can be used.

The base profile 3 is preferably provided on the inside with an insulating material 6.

Light cutters can be manufactured in the factory in running lengths and cut on site as needed. It is also possible to manufacture the base profiles and cover layers separately and join them together at the construction site.

The interconnection of the light dowels into a building component can take place partly with locking profiles 7 and partly also with supplementary cassettes 8, which are installed between adjacent base profiles 3.

The function of the locking profiles 7 is to fasten the opposite edges of the cover layers 4 to each other and the profiles can have any suitable appearance. Figure 6 shows an example of such a locking profile consisting of a sheet metal strip 9 provided with a plurality of slots 10 extending some distance inwards towards the center of the strip 9. By folding the sheet metal parts between the slots 10 alternately to the left and right at both the lower and upper edges, as shown in the lower part of Fig. 6, a number of locking lugs 11 are obtained, which are placed on opposite sides of the cover layer. To facilitate attachment, the locking lugs 11 may be prefabricated along the length of one edge of the sheet metal strip 9, after which the strip is placed on the second cover layer, and the tabs on the opposite side of the sheet metal strip are folded down against the adjacent cover layer as shown in the figures. The locking profile 7 thus causes the cover layers to adhere. The lugs 11 can also be provided with spikes that adhere to the cover layer material.

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A refill cartridge of suitable material can be installed between the base profiles 3. The cartridge may be convex in shape as shown in Figure 1, but may equally well be flat or concave or of some other shape. To secure the cassette, it can be provided with protruding pins 13 which protrude into corresponding holes in the sides of the base profile. Alternatively, grooves 17 can be formed in the sides of the base profile 3, into which the side edges of the refill cassette go. The refill cassette 8 can be mounted at a suitable height with respect to the base profile, and can thus be mounted to run flush with the underside of the base profile or, as shown in Figure 1, with some retraction from this underside. It may often be appropriate for acoustic reasons to install the refill cartridge retracted, and this may result in a more pleasing appearance in addition to the technical advantages. An insulating layer 14 can be installed on the upper side of the refill cassette 8, and ventilation pipes, or electrical wires, water and telephone wires 15, etc. can be placed inside or above the secretion layer.

According to the invention, there is provided a statically cooperating, load-bearing unit of a thin sheet metal base profile which cooperates with a cover layer of plywood or some other wood-based material by means of an adhesive joint. The perfect co-operation achieved by the adhesive joint forms an essential basis for the lightweight truss according to the invention to have very good load-bearing properties. To illustrate this, reference is made to the accompanying drawing, which shows a stress-strain diagram in which the compressive stresses of the parts used and the ideal compressive stress of the combined light weight (plate + adhesive flange) are located on the vertical axis and the deformation is placed on the horizontal axis.

In order to examine the stress-strain curve, the properties of the components mentioned in the diagram are started, and on the basis of this, the values of the combined light dance unit can be determined. Thanks to the complete co-operation of the plywood board and the sheet metal material (adhesive flange) provided by the adhesive connection between these components, the tension normally allowed for the sheet metal material in the vicinity of the top flanges of the sheet metal profile can be exceeded without compromising the overall structure.

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In Fig. 7, the curve Ea depicts the modulus of elasticity of the sheet metal material, the curve Ey the elastic modulus of the plywood material, and the curve E1 the ideal modulus of elasticity of a fully cooperating lightweight punch unit. If the area of the sheet material is denoted by Ay and the area of the sheet metal material (adhesive flange) is Aa, then the ideal modulus of elasticity of the combined lightweight punch unit is given by the following formula E ^ = (Ey · Ay + Ea · Aa) / (Ay + Aa). In the diagram, aa is the normally allowed stress for the sheet metal material and ay is the normally allowed stress for the plywood material.

If now the intersection of aa and the curve Ea is connected by a line to the intersection of ay and the curve Ey, then this line intersects the ideal modulus of elasticity E ^ at the point of the line or curve (ai; no). It is found that when the sheet and the adhesive flange work together and the deformation is E-j, the stress aai of the sheet material is higher than the stress aa normally allowed for the sheet material, and that the stress ayi of the plywood material is lower than the stress ay normally allowed for the plywood material. Thus, with the complete co-operation of the components, the σ value of the sheet metal material can be increased compared to the case where the sheet metal profile and the plywood material are joined together only by mechanical bond and do not achieve the perfect interaction caused by the adhesive joint.

The relative increase in the surface area of the plywood material compared to the surface area of the sheet material in the adhesive flange causes the curve Ej to approach the deformation curve Ey of the plywood material, and the relative proportion of plywood to load in the combined element (board + adhesive flange) increases, and the plywood tension ayi approaches nity aai in the adhesive flange of the sheet metal material increases and approaches the yield point as. This can take place without compromising the overall security of the structure, for the reason that the reduced security of the sheet metal material is replaced by the increased security of the plywood material.

Thus, as can be seen from the above, without increasing the dimensions of the sub-components used, the combined lightweight punch unit can be provided with a substantially higher load-bearing capacity than a structural unit in which the sheet metal profile and the cover layer are joined together by mechanical bonding.

In a practical embodiment of the invention, a roof beam of a flat water roof with a span of 12 m was made from lightweight dome elements according to the invention. The profile height of the parent profiles was

Claims (4)

6 60902 about 25 cm and were made of thin sheet metal 1-1.25 mm thick. The distance between the light dance elements was 120 cm, and the width of the base profile was 60 cm. The top layer consisted of 19 mm thick plywood. Calculations as well as practical experiments have shown that the bearing capacity of this water roof is very good despite its large span and the relatively large distance between the base profiles. It is to be understood that the foregoing description is by way of example only and that all modifications of the invention may be made within the scope of the appended claims. It is still obvious to a person skilled in the art how the invention can be modified by exchanging materials and elements for corresponding materials and elements without departing from the basic idea and spirit of the invention. A component made of a plurality of lightweight dowel elements for mounting horizontally between load-bearing points for loading from above, characterized in that each lightweight dance element (1, 2) consists of a lower, tensile stress-absorbing base profile consisting of an upwardly open (thin) sheet metal profile having inwardly or outwardly bent flanges (3a) on the upper side and an upper layer (4) of plywood or other wood material intended to absorb compressive stresses and made of a material which is considerably stiffer in all directions than the base profile damper, and that the cover layer is firmly attached to the base profile (3) by an adhesive seam (5) extending over the entire surface of the upper surface of the base profile flanges (3a), so that the cover layer (4) and the base profile (3) form a statically cooperating, supporting unit. Building component according to Claim 1, characterized in that the cover layer (4) of each lightweight dancing element (1, 2) is wider than the base profile (3) and extends along the length of each longitudinal side beyond the base profile (3). 1. The first source of the bellows element is shown on the horizon to be mounted on the horizon and the bellows of the bellows, the bellows element (1, 2) being mounted on the underside of the base profile