NL9301685A - Partition wall, and method for building a partition wall - Google Patents

Abstract

A laminated (layered) partition wall comprises: at least one supporting upright 50; a first wall layer 10, formed by at least two first construction panels 11, which at their edges 12, are attached to the supporting upright; and a second wall layer 20, formed by at least two second construction panels 21 which, at their edges 22, are attached to the supporting upright, opposite the first construction panels 11, so that a cavity 51 is located between the first and second wall layers. Between the first wall layer and the supporting upright there is a third wall layer 30, formed by at least one third construction panel 31, the coincidence frequency of which differs from that of the first construction panels, which third construction panel is attached to the supporting upright at a section which is removed from its edges 32, so that the said edges project outside the supporting upright on either side. <IMAGE>

Description

Title: Room divider, and method for building a room divider

The invention relates to a partition wall and to a method for building a partition wall, more in particular a layered partition wall which is intended to function as a non-load-bearing partition wall between two spaces, which partition wall comprises: at least one supporting post ; a first wall layer formed by at least two first construction plates attached at their edges to the support post; and a second wall layer, formed by at least two second construction plates, which are attached at their edges to the support post, opposite the first construction plates, so that a cavity is located between the first wall layer and the second wall layer.

Such partitions are known in practice and are used, for example, to divide an existing room into two or more smaller rooms, or to realize the final office layout in an office building.

In practice, requirements are imposed on a partition wall with regard to airborne sound insulation and thickness. On the one hand it is desirable to achieve good sound insulation between the two spaces to be separated, on the other hand it is desirable to make that partition as thin as possible, or at least not to exceed a certain maximum thickness (approx. 10 cm). Furthermore, it is desirable to save as much as possible on weight, and the aim is to manufacture the partition as cheaply as possible.

In the simplest embodiment, such a partition wall consists of two layers of flat plates mounted on both sides against the posts, for instance of wood, chipboard or plasterboard, so that the partition wall has a symmetrical structure. By way of example, drywall sheets are commercially available with standard thicknesses of 9mm, 12.5mm, 15mm, 18mm. In a particular, known embodiment of this dividing wall, plates of 12.5 mm are placed at a mutual distance of 70 mm, and a mineral wool insulation is arranged between the plates; in that case the airborne sound insulation is approximately Rw 46 dB.

Other embodiments are known in which the sound-insulating effect is improved with respect to the said known wall. However, drawbacks are always associated with such known techniques.

A first possibility is to widen the cavity between the construction plates by using thicker posts. A disadvantageous consequence of this is that the total thickness of the wall increases, which is at the expense of the usable floor surface. Moreover, the useful effect of this measure is very small: if in the above-mentioned example one broadens the cavity to 80 mm, one will generally achieve a barely measurable improvement, and at best an air-sound insulation of at most Rw 47 dB is achieved. .

As a second option, thicker plates can be used. However, this is only possible to a certain extent, because with the thickening the plates become more rigid, which actually results in better sound transmission or poorer insulation. Furthermore, the thicker plates are more expensive than the thinner plates, so that the wall becomes more expensive. If the cavity is kept at the same thickness, the aforementioned drawback is that the total wall thickness increases. If the total thickness of the wall is kept constant, the consequence is that the thickness of the cavity becomes smaller, so that part of the increase in insulation value offered by the thicker plates is lost.

One can go even further and apply multiple plates. For example, a partition wall is known, in which two layers of plasterboard sheets, each with a thickness of 12.5 mm, are mounted in a symmetrical manner on each side of the posts. The cavity has a thickness of 50 mm and is also filled with insulating material, and the total thickness of the wall is 100 mm. The soundproofing of this known wall is approximately Rw 49 dB. However, it will be immediately clear that this wall is much heavier, and is also much more expensive than the aforementioned wall: this increase in costs is caused by, on the one hand, a larger amount of required material, and on the other, a greater number of parts to be supplied, so higher transport costs. , and a higher number of assembly operations to be performed, thus higher labor costs.

A limiting factor here is the thickness of the cavity.

The cavity plays an active role in the air-sound insulation, and it has been found that the sound-insulating properties of the wall decrease sharply when the thickness of the cavity becomes too small. If one wishes to improve the described wall even further by using several and / or thicker plates, this therefore irrevocably has the consequence that the wall becomes thicker, heavier and more expensive.

As a third option, plates of a different material can be used. For example, gypsum fiber boards are also commercially available in the thicknesses mentioned. This material has a higher specific gravity than plasterboard and provides better sound insulation. By way of illustration, a wall consisting of two 12.5 mm gypsum fibreboards 70 mm apart, the cavity being filled with mineral wool, achieves an airborne sound insulation of approximately Rw 48 dB. Thus, while this choice of material provides an improvement in insulation from a partition wall constructed from plasterboard, the degree of improvement is unsatisfactory. In addition, this material has the disadvantages that it is more expensive and more delicate than plasterboard and that it is less easy to finish.

The object of the invention is therefore to provide an improved partition wall. More particularly, it is an object of the invention to provide a partition wall which, compared to the known four-layer partition wall, has the advantages of comparable or even better airborne sound insulation, comparable or even lower thickness, lower weight and lower costs. A special object of the invention is to provide a relatively inexpensive partition wall, the thickness of which is approximately 90 mm and the sound insulation of which is approximately Rw 50 dB, which is a magical limit in this field.

The invention is based on the insight that the coincidence frequencies of the plates, and thus the choice of materials of the plates, play a major role in the sound-insulating effect. The plates act as a barrier, as it were, with a certain weakening factor in a certain frequency range. It has now been found that, when using at least two wall layers placed against each other, wherein the construction plates of the adjacent wall layers have mutually different coincidence frequencies, for instance because the construction plates have mutually different thicknesses and / or are made of different materials, a surprisingly good airborne sound insulation is achieved even so well that it is sufficient to suffice with only one added wall layer with different coincidence frequency. It is important here that the seams occurring in the adjacent layers stagger relative to each other, in order to ensure that the sound-insulating effect at the position of the posts of the wall is sufficiently great. The posts, which serve to give the wall a certain strength and stiffness, precisely because of their stiffness form a bridge between the first and second wall layers along which the sound can propagate relatively well, and therefore form the weak point with regard to the sound insulation . Due to the traditional technique of attaching the construction plates with their edges to the posts, so that the seams between the construction plates are located at the posts, the construction plates offer relatively poor damping precisely at said sound bridge.

Therefore, the above objects are achieved with a partition of the aforementioned type, which according to the invention is characterized in that a third wall layer, formed by at least one third construction plate, whose coincidence frequency differs from that of the first, extends between the first wall layer and the supporting post. construction plates, which at least one third construction plate is attached to the support post at a part remote from its edges, so that the edges of said at least one third construction plate protrude on either side outside the support post.

A particularly preferred embodiment of the partition wall according to the invention is characterized in that the first and the second construction plates are plasterboard panels with a thickness of approximately 12.5 mm, that the third construction panels are plaster fiber panels with a thickness of approximately 15 mm, and that the cavity has a thickness of about 50 mm. This partition has a thickness of only about 90 mm, that is to say less than the total wall thickness of the said four-layer partition, but offers a sound-insulating effect of approximately Rw 50 dB when the cavity is filled with mineral wool, i.e. more than the sound-insulating effect of the said four-layer partition. From a technical point of view, this wall thus already offers an improvement over the aforementioned four-layered partition wall. In addition, the cost of this partition is lower than that of the aforementioned four-layer partition, because the number of parts to be transported and the number of assembly operations has been reduced. This preferred embodiment of the partition wall according to the invention moreover retains the finishing options of the known partition walls constructed from plasterboard panels.

Further aspects, features and advantages of the invention will be further elucidated by the following description of a preferred embodiment of the partition wall according to the invention, with reference to the drawing. Herein respectively show: figure 1 a partial, schematic horizontal section of a partition wall according to the invention; and figures 2A and 2B show a schematic horizontal section of known partition walls.

The layered partition wall 1 shown in Figure 1 comprises vertical uprights or uprights 50, which serve as reinforcement and mounting frame for partition wall 1. Since the nature and construction of uprights 50 is not the subject of the present invention, and knowledge thereof for understanding of the present invention is not necessary for a person skilled in the art, these will not be described in more detail. It suffices to note that the posts 50 may be standard commercially available posts, and usually consist of a metal profile. In the illustrative preferred embodiment of the partition wall as shown in Figure 1, the posts have a thickness of about 50 mm, so that a cavity 51 has a thickness D of about 50 mm.

The layered partition wall 1 comprises a first wall layer 10 and a second wall layer 20, which are provided on opposite sides of the post 50. The first wall layer 10 and the second wall layer 20 define a first main surface 2 and a second main surface 3 of the partition wall 1, respectively. which, after finishing with, for example, stucco and / or wallpaper, form the walls of spaces 4, 5 separated by partition wall 1.

The first wall layer 10 is formed by first construction plates 11. Likewise, the second wall layer 20 is formed by second construction plates 21. Such construction plates usually have a standard width of 120 cm, and the length thereof is matched, in advance or on site, with the height of the spaces 4, 5. The construction plates 11, 21 are fixed to the posts 50 with their vertically oriented edge portions 12, 22. For this purpose, different types of fasteners are known in practice, and these can also be used in the partition of the present invention . It is shown by way of example in Figure 1 that a clamping profile 52 with an Ω-shaped cross section is used. The clamping profile 52 comprises a back 53 and two wings 54, with an upright section 55 between them, the length of which, measured in the direction perpendicular to the back 53, is less than the thickness of the construction plates 11, 21 to be clamped. A screw 56 extends through an opening in the back 53 and is bolted to the post 50 so that the wings 54 clamp the edges 12, 22 of the construction plates 11, 21 against the post 50.

It is clearly shown in figure 1 that at the position of the post 50 a first seam 13 is located between adjacent first construction plates 11. The width of that seam 13 depends on the nature and the dimensions of the fasteners 52 used, and can be minimal. in case the fasteners do not extend between the construction plates 11, for example in the case of screws directly engaging the plates 11. The same of course applies to a second seam 23 between neighboring second construction plates 11.

It will be clear that in practice the number of the construction plates 11, 21 depends on the desired length of the partition wall 1 and on the chosen standard width of the construction plates 11, 21. It will also be clear that the number of posts 50 in the dividing wall 1 depends on the desired length of the dividing wall 1 and on the selected standard width of the construction plates 11, 21. When the chosen standard width of the construction plates 11, 21 is 120 cm, the fixing posts will have a center-to-center distance of 120 cm, plus the thickness of the seams 13, 23. In general, construction plates with a width of 120 cm are still supported at a position at their center position by further posts, so that the distance between the posts is then about 60 cm amounts. This distance may deviate locally from said size if it has proved necessary to select the width of the construction plates 11, 21 differently, for instance when a door is included in the dividing wall, and / or at one end of the wall if the total length of the wall is not a multiple of 120 cm.

Reference is now made to Figure 2A, in which like or similar parts are indicated with like reference numerals as in Figure 1. Figure 2A shows a known two-layer divider 100, which consists solely of the posts 50 and the first and second construction plates 11, 21 attached thereto. A particular embodiment of this known dividing wall 100, wherein the first construction plates 11 and the second construction plates 21 are plasterboard panels, the thickness Dn of the first construction plates 11 and the thickness D21 of the second construction plates 21 being approximately 12.5 mm, and the thickness D of the cavity 51 being about 70 mm, realizes an airborne sound insulation of about Rw 46 dB when the cavity is filled with mineral wool.

Reference is now made to Figure 2B, in which like or similar parts are indicated with like reference numerals as in Figure 1. Figure 2B shows a known four-layer dividing wall 200, which differs from said two-layer dividing wall 100 in that between the post 50 and the first wall layer 10 a third wall layer 30 formed by third construction plates 31 is accommodated, and because a fourth wall layer 40 formed by fourth construction plates 41 is received between the post 50 and the second wall layer 20. The construction plates 11, 21, 31, 41 are identical to each other, and the seam 13, 23 between the construction plates 11, 21 is mounted flush with the center of the construction plates 31, 41. A particular embodiment of this known partition wall 200, in which the construction plates 11, 21, 31, 41 are plasterboard plates with a thickness of about 12.5 mm, the thickness D of the cavity 51 being about 50 mm, realizes an airborne sound insulation of about Rw 49 dB when the cavity is filled with mineral wool.

Reference is now again made to figure 1. According to the invention, the dividing wall 1 is a three-layered dividing wall, in which a third construction plate 31 of the third wall layer 30 is not aligned with the first and second construction plates 11, 21 but is just attached to the supporting post 50 at a part of its edges 32, so that the edges 32 of said third construction plate 31 project on either side outside the support post 50. The third construction plate 31 thereby partly overlaps with a first construction plate 11 and with an adjacent construction plate 11.

Already by this construction the partition wall according to the invention offers advantages over the known constructions in that the bridge formed by the post 50 is shielded. Surprisingly, it has been found that for an effective shielding it is sufficient to suffice with the third wall layer 30, and that it is not necessary to design the wall symmetrically, as is traditional in this field. It is true that further soundproofing will indeed be achieved by applying a fourth wall layer symmetrically to the third wall layer, but to do this it is necessary to either reduce the cavity, which at the expense of the sound-insulating effect, or to reduce the total thickness of the wall. enlarge.

It is noted that the best sound-insulating effect is achieved when the cavity 51 is filled with insulating material, as known per se. However, the partition wall according to the invention also offers a clear improvement over the known constructions when the cavity is left open when the cavity is left open in these known constructions.

An additional advantage offered by the above-described construction according to the invention is that the shielding effect of the third wall layer 30 also has a favorable influence on the fire-resistant effect of the partition wall 1. The above-mentioned bridge effect of the post 50, together with the aligned seams 13, 23 of the first and second wall layers 10, 20 also form a weak point in the partition wall with regard to heat conduction, and thus with regard to fire resistance. A possible fire in one of the spaces 4, 5 will therefore first move along said seams to the adjacent space 5, 4. By applying the third wall layer 30 according to the invention, the fire resistance is considerably improved, regardless of whether the fire is located on the side of the double wall layers 10, 30 or on the side of the single wall layer 20.

In the illustrated embodiment, the screw 56 extends through the third construction plate 31, which may be provided with pre-arranged passage openings for this purpose.

The third construction plate 31 can be mounted symmetrically to the post 50, i.e. it can be attached to the post 50 near its centerline, but this is not necessary; in practice, the favorable effect according to the invention is already achieved when the third construction plate 31 protrudes at least on both sides outside the post 50. Nor is it necessary that the third construction plate 31 has the same width as the construction plates 11, 21, although this is preferable. In practice, it is even preferable to place adjacent construction plates 31 with their edges butted together, but this is not necessary either, because the first construction plates 11 already offer good sound insulation near their centerline.

According to a further aspect of the present invention, the first and third construction plates 11, 31 have different coincidence frequencies. This achieves the surprisingly good sound-insulating effect according to the invention. The explanation of this phenomenon is sought in that the plates 11, 31 acoustically function as serially placed barriers with mutually different coincidence frequencies, so that a better result is seen over the entire sound spectrum.

Changing the frequency of coincidence of the third construction plate 31 relative to that of the first construction plates 11 can be achieved by choosing a different material for the third construction plate 31 than the material of the first construction plates 11, and / or for the third construction plate 31 to select a thickness other than the thickness of the first construction plates 11.

For example, for the first construction boards 11, the material plasterboard board with a thickness in the range of about 9-15 mm can be chosen. This material, with a specific weight of about 1000 kg / m3, has the advantage that it is easy to process, has a nice smooth wall surface, and is relatively inexpensive. The second construction plates 21 can also be made of such gypsum cardboard plate.

For the third construction panel 31, a combination of the thickness and the specific weight is preferably chosen such that the specific weight of the panels, defined as weight per surface, is in the range of 10-22 kg / m2 but deviates from the specific weight of the first boards 11. A suitable choice for the third construction boards 31 is gypsum fiber board with a thickness in the range of about 9-21 mm. This material has a specific weight of about 1200 kg / m3, so that the specific weight at a thickness of 15 mm is 18 kg / m2. It is also possible to use a steel plate for the third construction plate 31, in which case a thickness of only 1-3 mm is sufficient, whereby a further reduction of the total thickness of the dividing wall can be achieved if desired.

A particularly preferred embodiment of the partition wall as shown in figure 1 has the following parameters: first construction plate 11: plasterboard material; specific weight approx. 1000 kg / m3; thickness about 12.5 mm; second construction plate 21: plasterboard material; specific weight approx. 1000 kg / m3; thickness about 12.5 mm; third construction plate 31: gypsum fiber board material; specific weight approx. 1200 kg / m3; thickness about 15 mm; cavity 51: thickness approx. 50 mm.

When the cavity 51 is filled with insulating material, this preferred partition wall offers a sound insulating effect of approximately Rw 50 dB, which is better than the sound insulating effect of the known four-layer dividing wall 200 (Rw 49 dB) and in this field achieving the magic limit. of Rw means 50 dB. Moreover, the preferred partition wall achieves this favorable result at a total wall thickness of only about 90 mm, which means a whopping 10 mm of space compared to the known four-layer partition wall 200. In addition, the preferred partition wall is cheaper than the known four-layer partition wall 200, since the number of transport and construction plates to be treated have been reduced by approximately 25%.

It will be clear to a person skilled in the art that it is possible to change or modify the illustrated embodiment of the device according to the invention without leaving the inventive idea or the scope of protection.

For example, it is possible that the number of applied layers is increased. It is then possible to choose the thickness of the plates increasingly smaller in order to achieve the same total thickness, or to allow the total thickness to increase.

In all the cases mentioned, the advantage offered over the known technique consists of a sound insulation which is improved compared to the sound insulation as was achieved with the known techniques at the same total thickness.

Furthermore, it is possible that the mounting plate for the construction plates comprises fixed, and extending perpendicularly, between the posts. It is also possible, although less desirable, for the posts to be vertically designated in the description to extend horizontally.

Furthermore, the third construction plates 31 may have a smaller width than the first construction plates 11.

Claims (8)

A layered dividing wall, comprising: at least one support post (50); a first wall layer (10) formed by at least two first construction plates (11) attached at their edges (12) to the support post (50); and a second wall layer (20), formed by at least two second construction plates (21), which are attached at their edges (22) to the support post (50), opposite the first construction plates (11), so that between the first wall layer ( 10) and the second wall layer (20) is a cavity (51); characterized in that a third wall layer (30) extends between the first wall layer (10) and the support post (50), formed by at least one third construction plate (31), the coincidence frequency of which differs from that of the first construction plates (11) , which at least one third construction plate (31) is attached to the support post (50) at a portion remote from its edges (32), so that the edges (32) of said at least one third construction plate (31) project on either side outside the wearing style (50). Partition wall according to claim 1, characterized in that the material of the at least one third construction plate (31) differs from the material of the first construction plates (11). Partition wall according to claim 1 or 2, characterized in that the thickness of the at least one third construction plate (31) differs from the thickness of the first construction plates (11). Partition wall according to any one of the preceding claims, characterized in that the first construction panels (11) are plasterboard panels with a thickness in the range of 9-15 mm; that the second construction boards (21) are plasterboard boards with a thickness in the range of 9-15 mm; that the third construction boards (31) are gypsum fiber boards with a thickness in the range of 9-21 mm; that the thickness D of the cavity (51) is selected in the range of 50-70 mm; and that the total thickness of the dividing wall (1) is in the range of 77-105 mm. Partition wall according to claim 4, characterized in that the first construction panels (11) are plasterboard panels with a thickness of approximately 12.5 mm; that the second construction boards (21) are gypsum board boards of about 12.5 mm thickness; that the third construction boards (31) are gypsum fiber boards with a thickness of about 15 mm; that the thickness D of the cavity (51) is about 50 mm; and that the cavity (51) is filled with insulating material, so that the total thickness of the dividing wall (1) is approximately 90 mm and the sound insulation of the wall is approximately Rw 50 dB. Partition wall according to claim 1, 2 or 3, characterized in that the third construction plates (31) are metal plates with a thickness of about 1-4 mm. Method for placing a layered partition wall (1), comprising the steps of: - placing at least one support post (50); - applying a first wall layer (10) and a third wall layer (30) to a first side of the support post (50) by attaching at least two first construction plates (11) to the support post (50) at their edges (12) with between the first construction plates (11) and the support post (50) a third construction plate (31) whose coincidence frequency differs from that of the first construction plates (11), such that the edges (32) of said third construction plate (31) protrude on either side outside the support post (50) and overlap with the edges of said first construction plates (11); and applying a second wall layer (20) to the opposite side of the support post (50) by attaching at least two second construction plates (21) to the support post (50) at their edges (22). Method according to claim 7, characterized in that plasterboard sheets with a thickness of about 12.5 mm are used for the first wall layers (10); that for the second wall layers (20) plasterboard sheets with a thickness of about 12.5 mm are used; that for the third wall layers (30) gypsum fiber boards with a thickness of about 15 mm are used; that a post (50) with a thickness of about 50 mm is used, so that the thickness D of the cavity (51) is about 50 mm; and that an insulating material is applied in the cavity (51), so that the total thickness of the dividing wall (1) is approximately 90 mm and the sound insulation of the wall is approximately Rw 50 dB.