NO145584B - COMPOSITE WALL STANDS. - Google Patents

Description

The present invention relates to a composite wall-

stands, especially for house construction.

A very common construction of walls in buildings is the truss construction, which is composed of a lower horizontal foundation, an upper horizontal beam, the so-called hammer band, and standing uprights placed between these. Such truss constructions are not only used in smaller buildings, but also

in rather large buildings with several storeys, whereby the truss construction in the lower buildings is usually arranged throughout the entire height of the building, but in buildings with several storeys it is usually arranged separately between two superimposed joist layers. The truss construction is usually on both sides, e.g. as regards an external wall both on the outside and on the inside, provided with a sealing layer of an appropriate material, and between the studs included in the truss construction or the two sealing layers are provided with insulating material, partly to provide thermal insulation, partly also to provide sound insulation. An insulation material that often occurs is mineral wool in disc form.

The balance between fixed construction costs for thermal insulation and variable costs for heating fixed assets has been subject to changes in connection with the increased costs of fuel for heating purposes, and efforts have been made to appropriately increase thermal insulation to achieve the best total economy. This applies in particular to external walls in buildings.

This tendency quickly leads to thicker construction dimensions on both the stud structure and the insulation that is placed within the stud structure. As an example, it can be mentioned that previously in wooden buildings a stud dimension was often used

2" x 4" = 8 square inches, but that today, to a large extent, they have switched to a stud dimension of 1.5" x 5" = 7.5 square inches. It is of course not appropriate from a durability point of view to reduce the cross-sectional area of the uprights, and the insignificant reduction of the cross-sectional area represented by the two above-mentioned dimensions is not considered to be of importance. As a rule, however, the cross-sectional surface of the uprights must be maintained as far as possible in order for these to provide the necessary carrying capacity. If one were now to increase the size of the studs further in the direction of the thickness of the wall in order to thereby be able to insert an even thicker and more effective insulation layer, one would therefore be able to choose between making the studs so thinly dimensioned in a direction parallel to the plane of the wall that they would be exposed to too great a risk of buckling under the influence of pressure from above, or to deviate from the principle of keeping the cross-sectional area constant. Such a flimsier stand in the plane of the wall would also cause further difficulties in that it would be far too flimsily dimensioned to withstand the impact of the necessary nailing. If, on the other hand, one maintains the dimension in the horizontal direction in the wall's own plane at said values of e.g. 2" or 1.5" while increasing the size of the stud perpendicular to the plane of the wall, other disadvantages occur. First of all, the stud construction with the increased amount of wood would be far too expensive, and on the other hand, the wood mass would act as a heat conductor to a greater extent than is the case for the insulation, and the purpose of the wall thickness increase, namely improved thermal insulation, has thus been counteracted. Up until now, therefore, it has been necessary, when choosing a pillar construction and dimension, to accept a more or less unfavorable compromise between costs for the construction and the desired improvement in the heat economy.

This entails a disadvantage that has been tried to be avoided in various ways. One way to avoid this disadvantage has been to carry out the stud construction of profiled iron, but this solution to the problem is not satisfactory for several reasons. On the one hand, iron's thermal conductivity is even better than that of wood, on the other hand there are constructive difficulties when joining wooden parts and iron parts, and on the other hand an iron stud construction is ultimately more expensive than a wooden stud construction both in terms of material costs and costs for erecting the construction. Another proposed solution to the problem has been to carry out the stud construction in two or more side-by-side stages, whereby one could have been dimensioned in a traditional way and acted as load-bearing, while the other, preferably, the outer stud construction could have been made of flimsier material without its own load-bearing capacity.

The latter proposal, however, leads to a significant complication in the building work and implies that the building process must be adjusted, which is also difficult or even impossible to implement in many cases, especially as it has proved necessary to adapt the flimsier stud construction for subjects of a different dimension than the subject in the load-bearing stud construction.

The present invention relates to a solution to the above-mentioned problem, which solution has been shown by practical tests to be free of all the above-mentioned disadvantages.

The invention thus relates to a composite road fence, especially for house building.

According to the invention, the stand ©» consists of two rigid surface layers with the same width and at least substantially the same length as the stand. The two surface layers are connected to each other

using strip-shaped spacers that run parallel to the longitudinal direction of the stud. In the space between the spacers or the surface layers are bodies of insulating material arranged.

In the following, the invention will be described in more detail in connection with the exemplary embodiments shown in the drawings, but it is understood that the invention is not limited to these particular exemplary embodiments, but that all kinds of different modifications may occur within the scope of the invention.

In the drawings, fig. 1 and 2 a couple of different embodiments of the uprights used according to the invention in a perspective view and with part of one surface layer removed to make it clear. the spender's interior. Fig. 3 and 4 show a section parallel to the long side or the short side of a cross section through the strut according to fig. 1 to clarify how its end part can be arranged. These two figures show the stand in a so-called separated projection. Fig. 5 and 6 show the same stand, although not in a separate projection, but otherwise in the same way as fig. 3 and 4. Fig. 7 finally shows the lower end of the stand according to fig. 3-6.

At the stand according to fig. 1 there are thus two cover layers 10 and 11, whereby a part of the cover layer 10 has been removed to make the manufacture clear. Between the two cover layers 10 and 11, two spacers in the form of wooden strips 12 and 13 are arranged, so that they lie at the long sides of the upright. The channel between the cover layers 10 and 11 on the one hand and the strips 12 and 13 on the other is filled with an insulating body 14, which in this case is assumed to be made of mineral wool, e.g. glass wool, rock wool or beaten gold.

If the insulation material is made of spun mineral wool,

special attention should be paid to the direction of the fiber plane with this mineral wool. It must be borne in mind that when spinning mineral wool, it is usually dropped from the spinning apparatus onto a traveling belt, but the belt moves here at a significantly lower speed

than the speed at which the fibers of mineral wool are produced in the spinning apparatus, and the consequence of this is that the fibers are dropped onto the belt in the form of windings and meanders that lie parallel to the plane of the belt. The mat thus formed is then compressed to form a disc of mineral wool to which is added a binder which is cured, so that the disc becomes approximately unchanged in shape. However, a tendency towards layer separation still remains due to the fact that the twists and turns that occur during spinning create layer planes that are parallel to the plane of the disk.

Most insulating materials are in reality more or less anisotropic, i.e. they have different properties in different directions, e.g. different tensile strength, compressive strength, etc. Often the direction of greatest tensile strength coincides with the direction of greatest stiffness. By using these properties in the right way, one can therefore counteract the deformation of the surface layers 10, 11 between the spacers 12, 13 which would otherwise occur when the upright is loaded in its. longitudinal direction which normally runs in the vertical direction. Because the upright is referred to as a component in a truss construction, a load occurs in its longitudinal direction. Mineral wool discs are typical exponents of such isotropic rna - terials. Thus, the largest mechanical parameters in terms of holding strength are in the direction of the layer plane, or in other words in the direction of the fiber plane. At right angles to the fiber plane, the tensile strength is very negligible. For this reason, the stud in the truss construction according to the present invention should be provided with a body of mineral wool with the direction for the highest holding strength, especially the highest compressive and tensile strength, perpendicular to the surface layer 10, 11. In this way, the mineral wool disc's mechanical properties are used optimally for providing highest possible holding strength for the stand.

One reason why mineral wool discs are preferred as insulation material in the uprights of truss constructions according to the present invention is precisely that they can be obtained at a low price, have very good insulation properties and are non-combustible, whereby a good fire safety is achieved which is not to be despised.

The target of the volume weight for the mineral wool disc used is based on a compromise approach. If you choose a disk with a low volumetric weight, the stand loses its holding strength. One should therefore be inclined to increase the volume weight of the mineral wool disc used, but if the volume weight is increased above a certain limit, the costs for the mineral wool disc instead become so great that the improved holding strength can be achieved more cheaply by using stronger dimensioned surface layers or by means of of closer spacers.

In practical experiments, it has emerged that the volume weight when using alas wool does not exceed 16 ka/m 3 or more than 120 kg/m 3, while e.g. for stone wool, the bulk weight should be between 35 and 250 kg/m 3. The best results are achieved with weights between 40 and 100 kg/m 3 for glass wool and between 80 and 200 kg/m<3> for stone wool.

Although the main holding strength against deformation, primarily bending, is achieved due to the surface layer, a not inconsiderable increase in holding strength is achieved from the insulation material. For this reason, the insulation material must be attached to the surface layer by gluing or the like. This can effectively prevent a pure buckling or buckling of the studs from occurring in normal load cases, but a certain tendency may remain of such a nature that a wave-like deformation could occur with alternate buckling and buckling of the surface layer. However, this tendency can, according to a further development of the invention, be counteracted by the introduction of additional strength-seeking and deformation-reducing members. An embodiment of the invention, in which such measures are taken, is shown in fig. 2.

In the embodiment according to fig. 2 you can thus find them again

the two surface layers 10 and o11 as well as the wooden strips 12 and 13, but in addition to these parts, a further wooden strip 15 has been installed. Between the strips 12 and 15 as well as between the strips 15 and 13, lamellas of mineral wool are laid in rows, 16 resp. 17. In order for these to provide the greatest possible support for the uprights, they are laid in with the fiber plane perpendicular to the strips 12, 13 and 15 at the same time as they are laid perpendicular to the long side of the upright cross-section. The mineral wool is further provided with a cut-in layer 18 of kraft paper or even more advantageously of cardboard, cardboard or other fairly rigid material. The surface layer 10 and 11 are attached both to the strips 12, 13 and 15 and to the surfaces of the mineral wool slats 16 and 17 which face the surface layer. In this way, a strikingly high increase in the holding strength against bowing of the uprights has been achieved, whereby they have become suitable for use in truss constructions according to the invention.

The thickness of the slats must be less than the distance between the surface layers 10 and 11.

The mineral wool filling provides a very strong increase

of the thermal insulation ability of these studs compared to the previously used studs made of solid material, e.g. wood, and the holding strength is completely satisfactory. However, to achieve the best thermal insulation, the surface layer should be made as thin as possible. This means that the slats, supported in the lateral direction by the mineral wool filling, will absorb the main part of the compressive load present in the longitudinal direction of the upright.

Investigations have also been carried out to confirm the appropriate dimensioning of the strips 12, 13 and 15. These investigations have indicated that of the combined cross-sectional area of the stud excl. the filling of mineral wool, or in other words the combined cross-sectional area of existing strips and surface layer, at least one third must be taken up by the two edge strips, in fig. 1 represented by lists 12 and 13, and likewise in fig. 2 represented by lists 12 <p>g 13, but not by list 15.

The surface layer can preferably be made of board, thicker wood fiber boards, chipboard or the like. As a rule, such have a sufficient resistance to pressure as long as buckling can be prevented, and their buckling is prevented by the adhesive connection with the strips and also to a certain extent with the mineral wool 14 in fig. 1 or the mineral wool lamellae 16 and 17 in fig. 2.

When installing an anisotropic insulation material, e.g. mineral wool, in the manner shown in fig. 1 and 2 with the layer planes, in which the material has its greatest compressive strength perpendicular not only to the surface layers 10 and 11, but also to the long side of the cross section of the strips 12, 13 and 15, this anisotropic material becomes compressible to a certain extent in the studs' own longitudinal direction . This circumstance can be used to facilitate the installation of the uprights in connection with the foundation or the hammer band. Some examples of this are shown in fig. 3-6 respectively on fig. 7.

Fig. 3 and 4 show the upper part of a stand for use in a truss construction according to the invention in longitudinal section, whereby the section plane in fig. 3 runs parallel to the long side of the cross section, and the section plane in fig. 4 runs parallel to the short side of the cross section. In order to provide a stable carrying

plan for the hammerband, an end piece consisting of two parts 19 and 20 has thus been arranged. Part 19 has a contour that corresponds to the outer contour of the stud, so that it is limited by the outsides of the strips 12 and 13 and on the surface layer 10 and 11, while part 20, which is attached to part 19, e.g. by means of nailing, screwing or gluing, or which may be continuous in one piece with the part 10, has an outer contour which corresponds to the inner contour within the strips 12 and 13 and the surface layers 10 and 11, so that an abutment is formed at 21, adapted for admission to the list 12 resp. 13 or the surface layer 10 resp. 11. The body consisting of parts 19 and 20 can then be pressed against the end surface of the upright, as shown in fig. 5 and 6, as well as being attached to the slats by means of nail connection 22. On the upper surface of part 19, the hammer band then finds good support.

If one arranges plates of the kind shown in fig. 3-6 both at the upright's upper and lower end, only one plate, preferably the one at the upper end, should be firmly anchored to the surface layer 10, 11 and the strips 12, 13, while the lower plate is removable.

At the lower end, the upright must be attached to the foundation 23, see fig. 7. In order to adapt the length of the upright, this is not provided at its lower end with cladding of the type shown in fig. 3-6. Instead, one can expediently cut bricks 24 with an outer contour that corresponds to the inner contour within the strips 12 and 13 resp. the surface layers 10 and 11. These blocks are attached by means of nail connection 25 to the foundation 23, after which the upright for the truss construction according to the invention is pressed down over the blocks 24 under compression of the mineral wool 14. To the right of fig. 7 thus shows a not yet completed connection between a strut 10, 11, 14 in a truss construction according to the invention and an underlying foundation 23, while on the left in the same figure the completed connection is shown. The connection can be suitably fixed using nails 26.

It should be noted that the compression of the mineral wool at the ends

on the stand in the manner shown in fig. 3 - 6 and on fig. 7, naturally means that any adhesive connection between the mineral wool on one side and the strips or the surface layer, on the other hand, must be broken up locally. However, it has been shown that this breaking up, which occurs by displacement in the adhesive connection's own planes, does not cause any difficulties whatsoever, as the greatest holding strength for an adhesive connection is perpendicular to the connection's own planes.

An assembly of the uprights in the manner shown in fig. 3-6 and on fig. 7 also leads to the significant advantage that one is not dependent on the accidentally available length of the uprights, but one can use a saw or other suitable tool to adapt their lengths for each particular need.

Claims (1)

1. Composite wall stud, especially for house construction, characterized in that it consists of two rigid surface layers (10, 11) with the same width and at least mainly the same length as the stud, that the two surface layers (10, 11) are connected to each other by using strip-shaped spacers (12, 13, 15) which edge to edge with the surface joint run parallel to the longitudinal direction of the upright, and that in the space between the spacers (12, 13, 15) resp. the surface layers (10, 11) are arranged bodies (14, 16, 17) of insulating material. 2. Wall studs according to claim 1, characterized in that the bodies of insulating material (14, 16, 17) are attached to the surface layers (10, 11) by means of gluing or the like, and are preferably also attached in a similar way to the spacers (12, 13 , 15). 3. Wall studs according to claim 1 or 2, characterized in that the spacers, which run along the edges of the studs, are so dimensioned that their cross-section represents at least one third of the stud's cross-section excl. the insulating bodies (14, 16, 17). 4. Wall studs; according to any of claims 1-3, characterized in that the insulation material in the insulation bodies (14, 16, 17) is anisotropic, and the direction of greatest tensile and compressive strength is perpendicular to both the surface layers (10, 11) and the spacers (12) , 13, 15) longitudinal direction. 5. Wall studs according to claim 4, characterized in that the insulating bodies (14, 16, 17) are made of mineral wool which is plastic bound and compressed. 6.. Wall studs according to claim 5, characterized in that the volume weight of the mineral wool, where it is made of glass wool, is between 16 and 120 kg/m , preferably between 40 and 100 kg/m 3 and, if it is made of rock wool, between 35 and 250 kg/m 3 , preferably between 80 and 200 kg/m 3. 7.. Wall studs, according to any of the preceding claims, characterized in that the insulating material body is made of lamellas (16, 17) with their planes perpendicular to the longitudinal direction of the stud, with thin layers of a support material (18), preferably kraft paper, cardboard, cardboard or similar inserted between the slats. 8. Wall stud according to claim 7, characterized in that the thickness in the longitudinal direction of the stud of each lamella (16, 17) in the insulation body is smaller than the distance between the surface layers (10, 11). 9. Wall stud according to any one of the preceding claims, characterized in that at least one short end of the stud is covered by a plate (19), which, at least mainly with its outer circumference, conforms in shape to the outer cross-section of the stud, in association with a second plate (20), which extends into the stud and which in its shape corresponds at least approximately to the inner circumference of the edge strips (12, 13) and the surface layers (10, 11) ). 10. Wall stud according to claim 9, in which both ends of the stud are covered by plates, characterized in that one plate is fixedly connected to the stud while the other is releasably connected to the stud to facilitate the cutting of the stud to the correct length. 11. Wall stud according to ler of 10, characterized in that the plate firmly connected to the stud (19, 20) is connected to the upright by means of a nail connection (22), which extends into the strips arranged at the edges (10, 11).