NL9900019A - Stiffened insulated sandwich panel for self supporting building system - Google Patents

Abstract

The sandwich construction insulation panel (1) is stiffened by metal sheet top-hat profiled members (2) fixed lengthwise to one face and secured by blind-riveting through thin angle members (8). The cavity in the member (2) may be filled with an insulating material glued in place. The larger profile may be fixed over the member (2) with the interspace filled with a fireproof insulating core providing increased stability. Stiffening members may optionally comprise lightweight Z-trusses similarly fixed to either surface of the panel according to the proposed use.

Description

Construction system

The invention relates to a building system for a self-supporting construction, which system comprises a combination of hollow panels made of sheet metal, the cavity of which is completely or partially filled with a building or insulating material, with at least one metal-shaped support which is corner profiles is attached to the panel.

Such a system is known from French patent application 2418415.

The invention has for its object to be an improvement over this known system, which improvement is largely formed by the use of a relatively lighter and yet stable construction which is particularly suitable for setting up a shed or storage space sufficient for all building requirements in a short time. To this end, according to the invention, a (relatively) slender profile is attached to the panel with a second profile perpendicularly above it, which profiles are connected to each other by rod-shaped elements arranged in a zigzag manner.

In a favorable embodiment the second profile is the same as the first profile with a panel also attached to this second profile.

A preferred embodiment is characterized in that bars are connected to it at an angle between the top or outside profile and a panel.

The invention will be explained in more detail below with reference to the figures, in which features and other advantages will emerge.

FIG. 1 and 2 show parts, in particular panels from the building system of which the invention is based;

FIG. 3 shows a building system according to the invention in which a panel according to figures 1 and 2 is applied;

FIG. 4 shows the system in which two panels are used;

FIG. 5 shows a framework of the building system according to FIG. 3;

FIG. 6 shows another favorable embodiment of the building system;

FIG. 7 shows a special embodiment of two panels;

FIG. 8 shows a special embodiment of a flat panel;

FIG. 9a - 9c show different facade and roof constructions in which the building system according to the invention is applied.

According to the invention, in the building system according to FIG. 3 applied the principle whereby the panel 1 is stiffened and made into a supporting element also by using (relatively) slender profiles 10, 11 and 12 which are stabilized against kinking by the panel 1 itself.

The roof and / or wall element according to figure 5 is thus composed as follows:

A panel 1 is provided with a slender profile 10 which is placed on its cover layer 1a and thus fixed at several places. A second profile 11 is arranged perpendicularly (in relation to the cover surface 1a of the profile 1) above the profile 10 at some distance and parallel thereto. Both profiles 10 and 11 are connected to each other by profiles 12 arranged in a zigzag fashion. By bending the ends 11a and 11b, see figure 5, from the profile 11 to the profile 10, node A placed on the cover layer 1a, a favorable combination of panel lattice girder. The forces that occur when this combination is bent mainly manifest themselves as internal forces in the truss construction. The attachment between trusses 10, 11, 12 and the panel 1 is subject to a weaker load due to the bending.

It may be clear that when bending the structure, the nodes A must transfer large forces from profile 10 to profile 11 as a result of the relative changes in length between these profiles associated with the bending. In fact, the force level is highest here. The slanted profiles 12 are loaded relatively lightly, so that even lighter profiles can be used for this.

For a normal commercial width of the panel 1 and for spans of up to approximately 30 m, the following profiles can be used, for example:

Profile 10: U-profile 35/45/35 * 2 Profile 11: tube around 38 * 1.5 Profile 12: tube around 27 * 1.5

These relatively thin profiles can easily absorb the forces without exceeding the permissible material stresses. However, in order to prevent such a framework being installed in insulation far before reaching the permissible stresses, even if the stability limit is exceeded by buckling of the profiles, it is not possible to provide the desired bearing capacity and stiffness according to a favorable measure. the desired stability is achieved because bars 13 are connected to the panel 1 from the outer profile 11. A preferred embodiment is herein characterized in that the rods 13 lie in a plane perpendicular to the framework formed by the profiles 10-12.

With regard to the stabilization of the embodiment according to figure 3 (and 4), the following can also be noted:

The U-profile 10 is stabilized in this plane by mounting on the cover surface of the panel 1 by the cover surface itself. Perpendicular to this plane, the stabilization is effected partly by the (sandwich) panel 1 and partly by the oblique profiles or bars 12. Thus, the number of oblique profiles 12 and the number of connections or bars 13 with the cover surface of the panel 1 are sufficiently large. sufficient stability can be obtained for the required function in two mutually perpendicular planes. The tube profile 11 obtains stability, in the direction perpendicular to the cover surface, through the oblique profiles 12. Since these profiles are connected to the panel 1, directly or by means of the profile 10, the final stability in this direction is applied by the panel 1. In the direction parallel to the cover surface, the stability for profile 11 may not be entirely sufficient to use the construction as such. By also placing bars 13 obliquely from profile 11 to the panel 1 and outside the plane of the truss 12, the profile 11 is supported against the panel. The component of this support parallel to the deck surface provides stability in this direction.

The embodiment according to Figure 4 is similar to that according to Figure 3 with regard to the slender profile structure; however, it is favorable here that the round profile 11 is replaced by the U-profile 10 to which a panel 1 is attached. As a result, it appears that the bearing capacity of the trusses then obtained is advantageously increased considerably, factor 6-8.

And last but not least; with the stabilization of the profile 11 (or 10 in Fig. 3), the framework is also sufficiently stabilized because the profiles / rods 12 and 13 are sufficiently short in length to take up the loads without kinking without extra provisions.

A favorable variant of the embodiment of the building system according to figure 3 is shown in figure 6 and is now characterized in that slender profiles 8 are provided on one or more panels 1 which are zigzag on only one spaced apart slender profile 11 rods 14 arranged in an inclined manner are connected. The functions of the profiles / bars 12 and 13 are hereby accommodated in one bar. In the embodiment shown, two panels 1 are laterally connected to each other by appropriate means 15. Both panels are provided with a slim profile 8 and now only one (round) profile 11 is placed above the panels 8 parallel to the profiles 8. The profiles 8 are then connected to the profile 11 by inclined bars 14 in a zigzag pattern. Furthermore, it is important that the two panels are properly connected to each other so that the tension forces occurring during bending do not drive the two panels apart. For this purpose, provisions can be provided in the form of coupling elements 15 between the profiles 1. By arranging these coupling elements 15 in a zigzag form, the entire construction becomes extra torsionally stiff, so that very large spans can be realized without the need for additional elements. to link the hall sections together. This can be important, for example, for the construction of hangars for large aircraft, so that construction can be carried out lighter.

If panels of suitable dimensions are used, it is also possible to provide only one panel with two profiles 8 and to fix the zigzag-shaped pattern of the bars 14 thereon. In this embodiment the occurring tension forces are absorbed mainly by the cover layer of the panel 1.

Another advantageous embodiment according to the invention is shown in Figure 7. Here, a panel 1 is converted at a suitable angle a and provided on the sides with likewise relatively slender profiles 16 which can be connected to each other, such that this system also meets the requirement for the safe assembly of zigzag shaped walls and / or roofs.

The extent to which the panels 1 stabilize the fitted profiles 16 against kinking depends essentially on the angle α with which the panel 1 is set. This angle then also determines, based on a certain load and longitudinal dimension of the panel 1, the minimum slenderness of the profiles 16 arranged in the sides. This slenderness is important because when placing the profile 16 within the cover layers 1a of the panel 1 , a slim profile a smaller interruption of the panel material (insulation) than a thicker profile. In the limit case, the profile 16 then reduces to a solid bar or strip, which offers the best solution economically. By providing the panels 1a according to the system of Figure 7 with the usual male-female couplings 16 adapted to the angle a between the panels 1, these panels can thus also be formed into walls and roofs. The profiles present at the location of these couplings are in principle available for mounting the fastening elements with which the panels 1a can be mutually connected.

Figure 9 shows another favorable embodiment in which now a side 17 of the (flat) panel 1b is turned over at an angle β and the opposite side is provided with the slender profile 16. As already stated above, the extent to which the profiles bend are stabilized away from the angle a or β at which the panels 1a or 1b are connected to each other. The optimum height of the truss is now also obtained by the embodiment according to Figure 8.

In order to manufacture complete buildings with panels 1a or 1b according to the system of Figs. 7 or 8, the ends of any of the component panels must be chamfered in known manner by cutting or sawing, otherwise the elements of walls and roofs will not be cracked ( insulation requirement) can be connected to each other.

An application example of a building system as shown, for example, in Figure 3 is shown in Figures 9a - 9c. The building systems set up and interconnected form a section of a hall. For a hall with a flat roof, fig. 9b, 3 building systems are the minimum; for a hall with a gable roof, fig. 9a, at least 4 building systems are required. Parts 17 are used which connect the profiles 11 of the systems as coupling bars. Arranging transverse angled profiles 18 and strips 19 creates moment-transmitting couplings when the parts 18 and 19 are connected both to the two adjacent (sandwich) panels 1 and to the two adjacent profiles 10. Such a hall section with a span of approximately 20 m and a panel width of 1.15 m has a rigidity per hall section corresponding to that of an IPE 270 profile, which amounts to an equivalent hall construction of per 1.15 m a gantry frame made of IPE 270 profiles.

It will further be clear that in all applications of the building systems according to the invention, a structure (walls, saddle roofs, saw-tooth roofs, etc.) is obtained which consumes considerably less material; a factor of great economic importance given the size of the construction sector.

Finally, it is stated that the panel 1 indicated above is a building element in the broadest sense and is therefore not limited to a sandwich panel. For example, panels can advantageously be used which possess certain properties due to their composition, for example are provided with light-transmitting parts.

(Conclusions)

Claims (6)

A building system for a self-supporting construction, which system comprises a combination of hollow panels made of sheet metal, the cavity of which is completely or partially filled with a building or insulating material, with at least one support formed from metal which is attached to the panel by means of corner profiles is attached, characterized in that a relatively slender profile (10) is attached to the panel (1) with a second profile (11) perpendicular to it, which profiles are connected to each other by rod-shaped elements (12) arranged in a zigzag manner . Building system according to claim 1, characterized in that the second profile is equal to the first profile (10) and a panel (1) is also attached to the second profile. Building system according to claim 1 or 2, characterized in that rods (13) are connected to it at an angle between the upper or outer profile (10, 11) and a panel (1). Building system according to claims 1 to 3, characterized in that the rods (13) lie on a plane perpendicular to the framework formed by the profiles (10-12) which form the attachment for a panel (1). Building system according to one or more of the preceding claims, characterized in that corner profiles (8) are provided on one or more panels (1) which are connected by means of zigzag-shaped bars (14) attached to them at a distance second profile (11) thereof. Building system according to one or more of the preceding claims, characterized in that a panel (1) is converted to an angle a to two panels (1a), the sides of which are attached to each other by means of profiles (16), a and others such that this system meets the requirement as set for zigzag shaped walls or roofs.