NL2013112B1 - Wall construction. - Google Patents

Abstract

The present invention relates to a wall construction, comprising: - at least two uprights; - at least two plasterboards which are each attached to at least two uprights and which span the space between the two uprights; - wherein at least two plasterboards are arranged on opposite sides of the uprights and enclose an inner space between the at least two plasterboards and uprights; - wherein the uprights are made of a material with a linear temperature expansion coefficient that is smaller than 10 x 10 6 mm / ° C at 20 ° C.

Description

Wall construction

The invention relates to a wall construction, more in particular to a construction for a partition wall or system wall.

Such dividing walls are generally known and are generally used for dividing up spaces in a property afterwards. The usual method of placing such a wall consists of mounting U-shaped metal-stud profiles on the floor and on the ceiling, between which generally C-shaped metal-stud profiles are spaced apart, for example 60 cm, as uprights. be placed. In this way a supporting structure is formed, against which plasterboards can be fitted. A space is created between the gypsum plasterboards and the profiles through which (electrical) pipes can be passed through and, if desired, filled with thermal and / or acoustic insulation materials. In addition to good sound-absorbing properties, rock wool also has beneficial fire-resistant properties.

Drywall comprises chemically bonded crystal water, which gives them good fire-resistant properties. If the plasterboard is heated by a seat of fire, this crystal water will evaporate and extract the energy required for the conversion from the fire.

As a result, the temperature rise of the plasterboard and the system wall construction is suppressed and kept virtually constant at about 110 ° C for a period, and the wall will last longer. During the fire, a layer of burned plaster develops, which has a higher thermal insulation. The glass fibers in the fire-resistant drywall act as reinforcement of the drywall, so that the structural cohesion during the fire load is even improved for a long time.

The fire resistance of the plasterboard is, just like other building materials, dependent on the entire construction in which it is used. For this reason, a fire resistance can only be assigned to the total construction. The present application relates to an improved wall construction, comprising one or more drywall.

If the temperature rises too high, the wall will eventually collapse. Especially with high walls this occurs faster, which can be explained by the longer length of the metal-stud profiles. As a result of the heating, the metal profiles expand, and the increased length will first clamp the metal-stud uprights between the floor and the ceiling, and cause it to bulge out with an even further thermal expansion. This causes the wall to collapse.

An object of the present invention is to provide a wall construction for a partition wall or system wall, wherein the disadvantages mentioned do not occur, or at least to a lesser extent. More in particular, an increased fire resistance is intended.

The said object has been achieved according to the invention with the wall construction according to the invention, comprising: - at least two uprights; - at least two plasterboards which are each attached to at least two uprights and which span the space between the two uprights; - wherein at least two plasterboards are arranged on opposite sides of the uprights and enclose an inner space between the at least two plasterboards and uprights; - wherein the uprights are made of a material with a linear temperature expansion coefficient that is smaller than 10 x 10 6 mm / ° C at 20 ° C.

By choosing a material with such a linear expansion coefficient, it is guaranteed that in the event of a fire the absolute expansion of the uprights remains within acceptable limits. This prevents the uprights from expanding so far that they bend outwards and cause the wall to bulge.

Such a limited linear expansion coefficient excludes the following materials, which exhibit an expansion coefficient expressed in mm / ° C at 20 ° C of: aluminum (22.2 x 106 mm / ° C), steel (12 x 106 mm / ° C) and stainless steel (stainless steel) (16 x 106 mm / ° C). Examples of materials that would be suitable are, for example, glass (7.6 x 10 6 mm / ° C. At 20 ° C) and plasterboard (5 x 106 mm / ° C at 20 ° C), as well as cardboard, bamboo, porcelain , and a fire-resistant version of an adhesive-bonded fiberboard, known as 'medium density fibreboard - fire resistant' and under the well-known abbreviation MDF-FR.

It is noted that the term drywall refers to both drywall and drywall panels, as well as fire-resistant drywall (e.g. types A, D, E, F, H1, H2, H3.1 and P).

It is also noted that the post can comprise a profiled beam-shaped body, for example with a U-profile or a C-profile, in accordance with conventional metal stud stands.

According to a preferred embodiment, the uprights are made of a material with a linear temperature expansion coefficient that is smaller than 8 x 10 -6 mm / ° C. at 20 ° C, and even more preferably less than 7 x 10 6 mm / ° C at 20 ° C.

According to a still further preferred embodiment, the posts are made of a non-metallic material. Metals usually have a high temperature expansion coefficient, which is undesirable for the wall construction according to the invention. A further disadvantage of a metal frame construction is that, via the so-called "Faraday cage", they can form an unwanted shield for indoor radiation, for example for a WiFi signal in an office building. By using non-metallic materials, this adverse effect of a conventional metal stud wall is prevented.

According to a still further preferred embodiment, the material of the uprights is selected from the group: cardboard, bamboo, porcelain, and MDF-FR, glass and plaster or combinations thereof. MDF-FR is a well-known abbreviation for the English name "medium density fibreboard - fire resistant", which is a fire-resistant variant of an adhesive-bonded fiberboard.

Surprisingly, a particularly advantageous embodiment is obtained if the uprights are made of cardboard. An upright made of cardboard, which is generally known to have a low ignition temperature, appears to be suitable for increasing the fire resistance of the entire wall construction compared to conventional metal stud profiles made of steel. Even if crystal water evaporates from the drywall as a result of the heating, the integrity will be preserved. The other well-known property of cardboard that it simply absorbs moisture is surprisingly not detrimental to the integrity of the wall construction. It has been found experimentally, however, that the use of cardboard uprights absorbs only a small amount of crystal water evaporating from the gypsum plasterboards, and remains below the ignition temperature of approximately 260 ° C of cardboard.

In addition, another effect that promotes the integrity of the wall construction can occur. The inner space is enclosed by the at least two plasterboards and uprights, is bounded at the bottom by the floor or a connecting member, and at the top by the ceiling or a connecting member in the form of a frame element to be discussed later. The inner space thereby forms a substantially airtightly sealed space, and in the event of a fire, the amount of air contained in this inner space will expand and increase the internal pressure, which guarantees the integrity of the structure. If crystal water evaporates from the drywall and is partially absorbed by the cardboard studs, the increased air pressure will press the cardboard against the drywall and prevent the cardboard stands from collapsing or falling apart. The internal air pressure that arises because the air trapped in the interior space expands as a result of the heat thus increases the rigidity of the wall construction.

A further advantage of using cardboard uprights is that cardboard is an easy-to-process material. As a result, it is possible that recesses for doors and frames can only be fitted at the desired location after a wall with uprights has been placed. For traditional construction with metal-stud profiles, the installation of windows and doors must already be taken into account when constructing. With metal-stud, this placement must therefore be fully decided in advance, while the cardboard posts according to the invention leave all options open. This is particularly advantageous for new construction.

The complete recyclability of cardboard, and the fact that cardboard can be offered everywhere as waste, is a further advantage. As a result, and partly because the production of cardboard is less energy-intensive than the production of metal-stud profiles, the use of cardboard uprights provides a sustainable solution.

According to a still further preferred embodiment, the cardboard uprights are impregnated to increase the fire resistance.

According to a still further preferred embodiment, the cardboard posts are at least partially plasticized to increase fire resistance.

If according to a still further preferred embodiment the uprights are provided with one or more perforations, an uprights is provided that can be easily glued. The glue then enters and through the perforations, and after curing will form a fixed glue joint. This greatly reduces the need for drilling in the structure.

A substantially flat wall surface is obtained if, according to a still further preferred embodiment, the wall construction comprises at least one connecting member, the connecting member comprising a shoulder part which is adapted to receive a wall connecting member lying substantially flat with an adjacent plasterboard. A flat wall has the advantage that there are no raised edges or deep seams in which dust can accumulate. As a result, such a wall is particularly suitable for an aseptic or dust-free room, such as an operating room or a clean working space, also referred to as a clean room. In addition, a flat wall is aesthetically pleasing.

If, according to a still further preferred embodiment, the connecting member is made of plaster, a material is used which exhibits good fire-resistant properties. In this way it can be prevented that metal or wooden elements are included in the wall construction.

An increased strength of the connecting member is obtained if the connecting member is made of glass fiber-reinforced gypsum.

According to a still further preferred embodiment, the wall connection member comprises a floor covering. Because this floor covering bends upwards from the floor and is received flush by the connecting member, or flush with an adjacent plasterboard, the floor covering overflows into an upright wall via a uniform curvature. This prevents sharp edges between floor and wall where dust can accumulate.

According to a still further preferred embodiment, the connecting member comprises a frame element, and the wall connecting element comprises a glass plate arranged in the shoulder part of this frame element. In this way a substantially flat, or "flush" connection can be obtained in a wall between a plasterboard and a glass plate. This makes it possible, for example, to provide an aseptic or dust-free room with a window, so that, for example, outside light can enter an operating room or clean room.

The fire resistance of the entire structure is determined by the weakest link. For this reason, according to a further preferred embodiment, a glass plate of fire-resistant glass is provided in the frame element.

According to a still further preferred embodiment, the frame element comprises two parts which are arranged on opposite sides of a post. By dividing the frame element, the sub-elements can be applied to uprights with different widths, whereby with a wide upright a seam can be present between the two parts of the frame element.

According to a still further preferred embodiment, the frame element forms a substantially airtight wall of the inner space, which is further enclosed by the at least two plasterboards and uprights and which is bounded on the underside by the floor or a further connecting member. If the frame element comprises two separate opposite parts, a possible seam between them is preferably filled in substantially airtightly, in order to close off the inner space substantially airtightly.

In the following description, preferred embodiments of the present invention are further explained with reference to the drawing, in which:

Figure 1: a schematic perspective view of a room with a partition wall provided with the wall construction according to the invention;

Figure 2: a front view of the wall construction shown in Figure 1;

Figure 3: a cross-sectional view according to the arrow III-III in Figure 2;

Figure 4: a cross-sectional view according to the arrow IV in Figure 3;

Figure 5: a cross-sectional view according to the arrow V in Figure 3; and

Figure 6: a cross-sectional view according to the arrow VI-VI in Figure 2;

The space shown in Figure 1 comprises a floor 1 and a (lowered) ceiling 2, between which a partition wall 4 according to the invention is arranged. This partition wall 4 is provided with a first recess 6 for a window 8, as well as a second recess 10 for a door (not shown). In the situation shown in Figure 1, a seat of fire F is located near the partition wall 4, which is heated thereby.

Figure 2 shows a front view of the wall 4, wherein the uprights 12 present in the wall, which will be explained in more detail below, are shown in dashed lines. Plasterboards 14 are attached to these uprights 12 with screws 18, and the space between the plasterboards 14 is filled flat with joints 16, so that a substantially flat, or "flush" wall 4 is formed.

The first recess 6 provided in the wall 4, in which a glass plate 24 forming the frame 8 is arranged, is bounded by a frame element 22 acting as a connecting member 20. This frame element 22 will be further elucidated with reference to Figures 3, 4 and 6.

A further connecting member 20 is formed by a corner connecting element 28, which comprises a shoulder part 30 which is adapted to receive a floor covering 32 lying substantially flat with an adjacent plasterboard 14 so that a substantially uniform continuous corner connection between the floor 1 and the wall 4 becomes obtained.

The frame elements 22 and the corner connecting elements 28 form connecting members 20 which are preferably made from plaster, and even more preferably from glass fiber-reinforced plaster.

In figure 3, supporting beams 24 are arranged on the ceiling (not shown), from which the lowered ceiling 2 is suspended. Disposed between the floor 1 and the supporting beam 24 is the partition wall 4, which in the embodiment shown in Figure 3 is of double-walled design and comprises two opposite wall parts.

Both wall parts comprise a plasterboard 14 and a glassboard 26, which are arranged in line with each other with a particularly elegant and fire-resistant connection, or "flush" with respect to each other.

Arranged between the wall parts are the uprights 12, which according to a particularly advantageous and surprising embodiment can be manufactured from cardboard. An upright made of cardboard, which is generally known to have a low ignition temperature, appears to be suitable for increasing the fire resistance of the entire wall construction compared to conventional metal stud profiles made of steel. Even if crystal water evaporates from the drywall 14 as a result of the heating, the integrity will be retained. The other well-known property of cardboard that it simply absorbs moisture is surprisingly not detrimental to the integrity of the wall construction.

The integrity of the wall 4 can be increased if the uprights 12 and the drywall 14 enclose an inner space 34 which is substantially airtightly bounded on all sides. On the underside this can be done by the floor 1 or a closing element 36, and on the top side by a frame element 22 (with or without a seal (not shown) in a seam 40 located between different parts thereof) or a closing element 38. At a fire will expand the amount of air trapped in this inner space 34 and increase the internal pressure, which guarantees the integrity of the wall 4. If crystal water evaporates from the drywall 14 and is partially absorbed by the cardboard uprights 12, the increased air pressure will press the cardboard against the drywall 14 and prevent the cardboard uprights 12 from collapsing or falling apart. The internal air pressure that arises because the air trapped in the inner space 34 has expanded as a result of the heat thus increases the rigidity of the wall construction.

By providing the uprights 12 and / or the closing elements 36, 38, and any side elements (not shown) with one or more perforations, they can be easily glued with an adhesive connection. The glue then enters and through the perforations, and after curing will form a fixed glue joint. This greatly reduces the need for drilling in the structure.

The frame element 22, which is shown enlarged in figures 4 and 6, comprises two parts in the embodiment shown. Although the person skilled in the art will realize that the frame element 22 can be manufactured from a single part, the use of two separate parts has the advantage that the frame element 22 with uprights 12 of different widths can be used. With a wider upright 12, a seam 40 will be created with some gap, which if desired can be sealed with a suitable (heat-resistant) seal.

The frame element 22 has a shoulder part 42 of such a depth that is substantially equal to the sum of the thickness of the glass plate 14 and the glue joint 44 with which it is attached to the frame element 22. This results in a substantially flat, flush connection between the plasterboard 14 and the glass plate 14 of the window 8. Such a wall is therefore particularly suitable for an aseptic or dust-free room, such as an operating room or a clean working space, also called clean room.

The embodiment described above, although showing a preferred embodiment of the invention, is only intended to illustrate the present invention and not to limit the description of the invention in any way. When measures in the claims are followed by reference numerals, such reference numerals only serve to contribute to the understanding of the claims, but are in no way restrictive of the scope of protection. The rights described are defined by the following claims in the scope of which many modifications are conceivable.

Claims (16)

Wall construction, comprising: - at least two uprights; - at least two plasterboards which are each attached to at least two uprights and which span the space between the two uprights; - wherein at least two plasterboards are arranged on opposite sides of the uprights and enclose an inner space between the at least two plasterboards and uprights; - wherein the uprights are made of a material with a linear temperature expansion coefficient that is smaller than 10 x 106 mm / ° C at 20 ° C. 2. Wall construction as claimed in claim 1, wherein the uprights are made of a material with a linear temperature expansion coefficient that is smaller than 8 x 10 6 mm / ° C at 20 ° C, and even more preferably smaller than 7 x 106 mm / ° C at 20 ° C. 3. Wall construction as claimed in claim 1 or 2, wherein the uprights are made of a non-metallic material. 4. Wall construction as claimed in any of the foregoing claims, wherein the material of the uprights is selected from the group: cardboard, bamboo, porcelain, and MDF-FR, glass and plaster or combinations thereof. 5. Wall construction as claimed in any of the foregoing claims, wherein the uprights are made of cardboard. 6. Wall construction as claimed in claim 5, wherein the cardboard uprights are impregnated to increase the fire resistance. 7. Wall construction as claimed in claim 5, wherein the cardboard uprights are plasticized to increase the fire resistance. Wall construction as claimed in any of the foregoing claims, wherein the uprights are provided with one or more perforations. 9. Wall construction as claimed in any of the foregoing claims, comprising at least one connecting member with a shoulder part which is adapted to receive a wall connecting member substantially flush with an adjacent plasterboard so that a substantially flat wall surface is obtained. 10. Wall construction as claimed in claim 9, wherein the connecting member is made of plaster. 11. Wall construction as claimed in claim 10, wherein the connecting member is made of glass fiber-reinforced plaster. 12. Wall construction as claimed in any of the claims 9-11, wherein the wall connection member comprises a floor covering. Wall construction as claimed in any of the claims 9-11, wherein the connecting member comprises a frame element and the wall connecting element comprises a glass plate arranged in the shoulder part of this frame element. 14. Wall construction as claimed in claim 13, wherein a glass plate of fire-resistant glass is arranged in the frame element. Wall construction as claimed in claim 13 or 14, wherein the frame element comprises two parts which are arranged on opposite sides of a post. 16. Wall construction as claimed in any of the claims 13-15, wherein the frame element forms a substantially airtight wall of the inner space which is further enclosed by the at least two plasterboards and uprights and which is bounded at the bottom by the floor or a further connecting member .