WO2013057384A1

WO2013057384A1 - Earthquake-proof wall

Info

Publication number: WO2013057384A1
Application number: PCT/FR2011/052414
Authority: WO
Inventors: Pauline Lopez; Pierre Bourgoin; Renato Talamonti; Roger Arese
Original assignee: Lafarge Gypsum International; Lafarge Boral Gypsum In Asia Sdn Bhd; Siniat
Priority date: 2011-10-17
Filing date: 2011-10-17
Publication date: 2013-04-25

Abstract

The invention relates to an earthquake-proof wall comprising: a primary framework including a lower rail fixed in a floor and an upper rail fixed in a ceiling, said rails being substantially horizontal, and two other substantially vertical rails fixed to walls, said rails having a substantially U-shaped cross-section; and a secondary framework including several substantially vertical posts, said posts having a substantially C-shaped cross-section, on which one or a plurality of panels are fixed. The wall is characterised in that the panels are fixed to the posts of the secondary framework, the posts having a smaller cross-section than the cross-section of the rails of the primary framework, the posts being partially or totally housed in the rails of the primary framework, and the posts being able to move relative to the rails of the primary framework in a horizontal and vertical direction.

Description

PARASISMIC ROOFING

The present invention relates to the construction of second work in seismic zone, and more particularly to partitions or contrecloisons.

When building a building, we can distinguish the supporting structure and the non-supporting structure. By definition, it is understood that the supporting structure is based on the foundations. The non-supporting structure is fixed to the supporting structure via a framework called primary framework. Non-bearing structures can themselves include, when necessary, a framework that is called secondary framework, attached to the primary framework. The non-load structure includes the assembly of various elements of the structure and in particular the assembly of plasterboard between them in order to define volumes inside the building. This assembly of panels requires fixing the panels on the secondary and primary framework.

However, during earthquakes, it is vital that buildings can withstand seismic stresses, and thus avoid collapse of the building. Many solutions exist to strengthen the carrier structure, but few solutions exist for the non-carrier structure.

Also it became necessary to find a way to avoid falling plasterboard during earthquakes thus avoiding damage to people and thus facilitated evacuation.

Also the problem to be solved by the invention is to provide a partition or contrecloison seismic resistant seismic forces.

Unexpectedly, the inventors have demonstrated that it is possible to separate the partition of the carrier structure, by setting up rails on the vertical and horizontal sides of the partition. This allows the supporting structure to move without transmitting the movements and constraints to the partition, and without shearing the fasteners that maintain the partition.

For this purpose the present invention relates to a seismic partition having:

a primary framework comprising on the one hand a lower rail fixed in a floor and an upper rail fixed in a ceiling, these rails being substantially horizontal, and on the other hand two other substantially vertical rails fixed on walls, these rails having a section substantially U-shaped;

a secondary frame comprising a plurality of substantially vertical uprights, these uprights having a section substantially in C, on which are fixed one or more panels; characterized in that the panels are attached to the studs of the secondary framework

the posts having a section smaller than the section of the rails of the primary frame;

the amounts being housed partially or totally in the rails of the primary framework; and

the posts being relatively movable relative to the rails of the primary framework in a vertical and horizontal direction.

The invention offers at least one of the critical advantages described below.

Advantageously, the earthquake-resistant partition according to the invention can withstand an earthquake without deteriorating or dissociating itself from the structure. Thus the seismic partition according to the invention does not collapse during an earthquake avoiding injury to the occupants of the structure.

Advantageously, the seismic partition according to the invention makes it possible to keep the escape routes of the structure available and free, without obstructing them.

Advantageously, the seismic partition according to the invention can remain intact during earthquakes of low or medium intensity, which makes it possible to accelerate the restoration of the building and to reuse buildings in a reduced time.

Advantageously, the earthquake-proof partition according to the invention can be produced at a lower cost, by using rails and commercial uprights.

Other advantages and characteristics of the invention will become clear from reading the description and examples given by way of purely illustrative and nonlimiting that will follow.

By the expression "supporting structure" is preferably meant according to the invention all the elements of a structure carrying more than their own weight. Examples of elements that can be carriers include poles, slats, floors, walls.

By the expression "primary framework" is preferably meant according to the invention all the rails and sleepers of wood or metal or of synthetic materials attached to the supporting structure of the construction or foundation and which serves as support for structural elements such as filler elements.

By the term "secondary framework" is preferably meant according to the invention all amounts and sleepers wood or metal or synthetic materials, held in place by the primary frame and which serves as a support for panels, electrical equipment, frames, frames, fills or cladding.

The term "partition" means both partitions and contrecloisons. The invention relates to a seismic partition having:

a primary framework comprising on the one hand a lower rail fixed in a floor and an upper rail fixed in a ceiling, these rails being substantially horizontal, and secondly two other substantially vertical rails fixed on walls, these rails having a section substantially U-shaped;

the amounts being housed partially or entirely in the rails of the primary frame; and

The primary or secondary frame of the earthquake-resistant partition according to the invention may be metallic or of wood, or of other materials. Preferably, the frame is metal.

The seismic partition according to the invention comprises a metal primary frame comprising an upper rail fixed to the ceiling and a lower rail fixed in the floor. These two rails are arranged in the same vertical plane. The seismic partition according to the invention also comprises two other rails fixed on walls. These rails of the primary frame can be arranged in the same vertical plane.

The rails of the seismic partition according to the invention have a substantially U-shaped section. It may be commercially available rails.

Preferably the wings of the rails have a wing height of at least 25 mm, preferably at least 40 mm.

Preferably, the metal thickness of the rails is greater than normal, preferably greater than or equal to 0.5 mm, more preferably equal to 1 mm.

The amounts of the secondary frame have a section smaller than the section of the rails of the primary frame. These amounts can be regularly spaced, and usually 40 or 60 cm.

The amounts of the secondary frame can be single or double, for example back to back or nested.

The amounts of the secondary frame can be substantially parallel. They can be arranged in the same vertical plane. The amounts of the secondary frame are housed partially or entirely in the rails of the primary frame. Thus it is possible to partially or fully encase the amounts of the secondary frame in the rails of the primary frame. For this it is sufficient to apply a slight pressure on the wings of the uprights and to slide them partially or completely into the rails. The primary framework completely or partially covers the wings of the uprights of the secondary framework.

The posts of the secondary frame can move relative to the rails of the primary frame in a vertical and horizontal direction. They can slide. Preferably the amounts are shorter than the height of the wall, 5 to 10 mm.

The panels of the seismic partition according to the invention are attached to the amounts of the secondary framework. Preferably, the length of the panel in the vertical direction should be 5 to 10 mm less than the total height of the partition. Preferably, the width of the panel in the horizontal direction should be 5 to 10 mm less than the total width of the partition.

The panels of the seismic partition according to the invention are not attached to the primary framework. These panels are independent of the primary frame and thereby the carrier structure, that is to say is disassociated.

The panels of the seismic partition according to the invention may be plates based on hydraulic binder. In this case these plates can be fixed, for example by screwing or gluing, on the uprights.

The hydraulic binder-based plate suitable for the partition according to the invention may be a cement slab or a gypsum board, preferably this slab is prefabricated in a prefabrication plant.

The cements suitable for the partition wall according to the invention may be based on Portland cement, cement described in accordance with EN 197-1, calcium aluminate cement or sulfoaluminous cement cement and mixtures thereof. Cements based on calcium aluminates, for example aluminous cements or Cements Fondus ^® , are also suitable according to the invention as well as cements conforming to standard NF EN 14647. The preferred cement suitable for cement sheets for the partition wall according to the invention is Portland cement, alone or mixed with other cements mentioned above, such as sulphoaluminous cements. Particularly suitable Portland cement is that described in accordance with EN 197-1. The cement slabs can be produced by various methods and in particular by non-continuous processes (for example molding, pressing, filtering, etc.). Cement plates said lightened by the incorporation of light loads are also suitable for the partition according to the invention. These light loads are usually derived from natural rocks or artificial rocks or are from petroleum products, for example polystyrene beads. Cement plates reinforced by the incorporation of fibers are also suitable for the partition according to the invention.

The gypsum board suitable for the partition according to the invention may be composed of a gypsum body cast at the factory between two sheets of paper constituting both its facing and its reinforcement.

Preferably, the hydraulic binder-based plate which is suitable for the element according to the invention is a plasterboard having a gypsum core whose density can vary as a function of the distance from the surface, with for example a low density core layer incorporating foaming agents into the paste, this core layer being sandwiched by high density surface layers (dense layer). An example of this type of plate is the conventional plasterboard of the type BA13 with dense layers.

According to one variant, plaster-based technical plates (with high tearing power) can also be used to improve the resistance of the partition to so-called remote shelves-type loads. For example, high density plates may be used having a density preferably of from 1 to 15 kg / m ² , more preferably from 12 to 14 kg / m ² such that the La Dura, Prégyfeu, PrégyWab plates marketed by the Lafarge Plâtres company.

The hydraulic binder plate suitable for the partition according to the invention comprises at least one facing. Conventional siding used in the manufacture of gypsum board is particularly suitable as for example the fiberglass facings. By way of example, cements made of cellulose fibers (paper, recycled paper), synthetic fibers (polyester, polypropylene, polyethylene, etc.) or inorganic fibers (siding made of fiberglass, ceramic fibers, etc.) may be mentioned. ). The facings may be woven or non-woven. For example, siding marketed by Johns Manville International, Inc. or marketed by Ahlstrom are suitable according to the invention.

In general, one of the sheets of paper used to make the plasterboard is dark in color, which may vary between a gray color and a brown color, because it is composed of cellulosic fibers that have not undergone a particular purification treatment . Conventionally, this gray paper is obtained from unbleached chemical pulp, and / or mechanical pulp, and / or thermomechanical pulp, and / or semi-chemical pulp. By mechanical pulp is generally meant a paste obtained entirely by mechanical means from various raw materials, mainly wood, which can be provided by wood-based recovery products such as old cartons, kraft paper clippings and / or or old newspapers. By thermomechanical pulp is meant a paste obtained by heat treatment followed mechanical treatment of the raw material. By semi-chemical paste is meant a paste obtained by removing some of the non-cellulosic components contained in the raw material by means of a chemical treatment, and requiring subsequent mechanical treatment to disperse the fibers. The other sheet of paper used to make the plasterboard has a visible face called cladding, which is generally lighter in color than the gray sheet.

The seismic partition according to the invention may alternatively have a space around the perimeter of the panel. This space allows the movement of the panel without damage or with less damage. The earthquake-proof partition according to the invention may comprise a seal of elastic material, this seal being located in the space around the periphery of the panel, between the bearing structure and the panel. This seal may be acrylic or silicone material. Preferably this seal is made of an intumescent material.

The invention will be described in more detail by means of the following examples, given in a non-limiting manner, in relation to the figures among which:

FIG 1 shows a perspective view, partial and schematic of an exemplary embodiment according to the invention of a partition;

FIG 2 shows another perspective view, partial and schematic and an embodiment of the invention of a partition.

For the sake of clarity, the same elements have been designated by the same references in the various figures and, in addition, the various figures are not drawn to scale.

The present invention will now be described by taking as an example boards, plasterboard. These plates are typically composed of a plaster body cast in the factory between two sheets of paper constituting both its facing and its frame.

Figures 1 and 2 show an embodiment of the invention of a seismic partition. The partition comprises a primary frame comprising a lower rail (1) fixed in the ground with screws and a vertical rail (4) fixed in the masonry wall with screws. The partition comprises a primary frame also comprising an upper rail (2) fixed in the ceiling (3). Alternatively the rails (1, 2, 4) can be glued to the floor, ceiling or wall. As a variant, the rails (1, 2) can be fixed to beams or a frame fixed to the ground or ceiling. The rails (1, 2, 4) are U-shaped metal rails. The partition comprises a secondary framework comprising uprights (6). These amounts are positioned vertically. The uprights (6) are U-shaped metal uprights. On these amounts are fixed with the aid of screw (9) plasterboard (7). The partition comprises a seal (8) around the perimeter of the plasterboard (7). The uprights (6) are partially nested in the rails (1, 2, 4). In particular one of the amounts (6) is partially housed vis-à-vis in the rail (4), the wings of the rail (4) covering the wings of the upright (6). Some other uprights have only their ends lodged in the rails (1, 2).

Claims

Seismic wall with:

a primary framework comprising on the one hand a lower rail (1) fixed in a floor and an upper rail (2) fixed in a ceiling (3), these rails being substantially horizontal, and on the other hand two other rails (4) substantially vertical fixed on walls, these rails having a section substantially U;

a secondary frame comprising a plurality of substantially vertical uprights (6), these uprights having a substantially C-shaped section, on which are fixed one or more panels (7); characterized in that the panels (7) are attached to the uprights (6) of the secondary framework

the uprights (6) having a section smaller than the section of the rails (1, 2, 4) of the primary framework;

the uprights (6) being housed partially or totally in the rails (1, 2, 4) of the primary framework; and

the uprights (6) being relatively movable relative to the rails (1, 2, 4) of the primary framework in a vertical and horizontal direction.

Seismic partition according to claim 1 characterized in that the panels (7) are not attached to the primary framework.

Seismic wall according to claim 1 or 2 characterized in that the amounts (6) of the secondary frame are substantially parallel.

Seismic partition according to one of the preceding claims characterized in that the panel (7) is independent of the primary framework.

Seismic partition according to one of the preceding claims characterized in that the primary or secondary frame is metal or wood.

Seismic partition according to one of the preceding claims, characterized in that the primary frame totally or partially cover the wings of the uprights (6) of the secondary frame.

7. Parasismic partition according to one of the preceding claims characterized in that it comprises a seal (8) of elastic material, this seal being located in the space around the perimeter of the panel (7) between the supporting structure the panel (7).