JPH02200277A - Temporary roof - Google Patents

Abstract

PURPOSE: To provide a space matched to the showpiece and to improve aesthetic appearance of an architectural showpiece by makign a ceiling by melting and bonding plural sheet materials with each other. CONSTITUTION: This temporary ceiling 10 can be made by forming a sheet material as a very long band material 6. In this case, a band material 6 has plural cross lines 7 made of melting materials placed at certain intervals in the length direction. And, plural sheets of the band material 6 are spread in parallel and tensed to form this temporary ceiling 1. As a result, the band material part of the temporary ceiling is dropped off by melting of the cross lines 7 caused by rising of the temperature due to a fire. Like this, it is possible to form a canopy by bonding each edge in lengthwise of the band material 6 with a melting material.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to a false ceiling, for example a false ceiling used in an exhibition building.

Generally a "canopy" used especially in exhibition buildings
The method of manufacturing false ceilings from woven fabrics, known as woven fabrics, is of great importance.

Exhibition buildings are usually tall structures to accommodate very tall exhibits, but when shorter exhibits are used, an intermediate board ceiling is installed. It is necessary to reduce the apparent height of the venue and hide the fixed structure from view. This false ceiling creates a space that matches the height and size of the exhibits, significantly improving the aesthetic appearance of the exhibit building.

Several methods have been used in the past to achieve such effects.

The oldest method involves horizontally stretching a canopy made of lightweight, flame-retardant cotton material over a large area.

However, this method is rarely used at present in most exhibition buildings for equipping them with smoke extraction equipment and automatic fire extinguishing systems. That is, in order for such a device to function, it is important that the center of the fire starting point coincides with the drainage head of the fire extinguishing device, which is fixed to a ceiling section located approximately vertically above this center. Specifically, the operation of the fire extinguishing system is initiated by hot air moving upward from the center of the fire outbreak area, and the fire is extinguished by directing a jet of water downward from the fire extinguishing system. In other words, the upward flow of hot air required to start the fire extinguishing system must not be stopped or diverted by horizontally located obstacles such as stretched fabric. It is.

Therefore, since it became common to equip exhibition buildings with such automatic fire extinguishing systems, conventional horizontal canopies have become unusable.

On the other hand, even if automatic sprinklers are not installed, the problem of smoke exhaustion remains. Proper smoke extraction equipment is extremely important for the safety of human life. That is, if a fire occurs and the smoke is not properly handled, the smoke not only suffocates people but also obstructs the visibility of the building's emergency exits.

Various other methods have been attempted in the past to enable the use of false ceilings while solving these extremely important technical problems.These methods will now be described.

The first method is to make the horizontally stretched woven fabric made of fire-resistant fibers, and to make the weave of these fibers large enough to form a net, which allows for the upward flow of hot air generated by a fire. At the same time, it allows the subsequent downward injection of jet water from the automatic fire extinguishing system.

However, in this method, the weave of the woven fabric cannot be made extremely large in order to sufficiently achieve the original purpose of the false ceiling, which is the shielding effect of hiding the superstructure of the building from view. Therefore, such false ceilings are not effective in practice, since sufficient ventilation and water permeability and sufficient concealment effect are incompatible.

The second method is to construct a false ceiling by folding a plurality of strips of flame-retardant paper nonwoven fabric, for example, in a zigzag shape. These strips are then hung vertically to form a honeycomb-like structure as a whole, for example.

This type of false ceiling is aesthetically pleasing and fully meets safety standards, so its utility value is high.
That is, this type of false ceiling does not impede the flow of the rising hot air flow or the water jet of the fire extinguishing system. However, due to its basic structure, this false ceiling is not homogeneous, nor is it aesthetically compatible with all types of exhibits.

A third method is to create a false ceiling by horizontally extending flaps made of a plurality of non-woven sheets that have been cut together in advance to allow the flow of hot air and fire extinguishing water jets. According to this method, it is of course possible to form a false ceiling with a homogeneous horizontal appearance, but such a false ceiling has many surface scratches and is also structurally complex and difficult to install. The problem is that it is troublesome.

[Problem to be solved by the invention]

The present invention aims to solve the above-mentioned conventional drawbacks all at once.

[Means to solve the problem]

The false ceiling according to the invention is characterized in that the false ceiling is composed of a plurality of sheet materials connected to each other by melting means.

(Operations and Effects) Therefore, the false ceiling of the present invention has a horizontal and uniform surface, so it is aesthetically pleasing, and has a relatively large area, so it can be installed and removed quickly, and can be removed easily. Since it has a smoke effect and an automatic sprinkler system can be activated immediately in the event of a fire, safety standards can be met.

〔Example〕

The false ceiling 1 according to the present invention uses a plurality of lightweight sheets of woven or knitted material or paper-like nonwoven fabric, and
It is formed by dividing these sheets into panels 2 of different sizes and shapes, and further connecting these peripheral parts to each other by means of molten material 3.

The panel 2 has a rectangular shape, for example, as shown in FIG. 1, and its dimensions are determined by the strength of the molten material 3.

As the melting material 3, materials having various properties and structures can be used.

For example, the molten material 3 can be formed from a raw material such as an alloy or a plastic resin.

Similarly, these fusible materials can be configured to connect the perimeter of the panel to each other in dots or continuously.

Alternatively, the false ceiling l may be constructed directly by connecting the panels 2 with the molten material 3, or the molten material 3 may be shaped into studs, rods, etc., and these may be used to connect the panels 2. It is also possible to use it indirectly, to fix the circumferential parts to each other.

Moreover, as a method of connecting the panels 2 with the molten material 3,
Adhesion or a mechanical fixing method may be used, and the molten material 3 is integrally formed with the sheet forming the panel 2,
It is also possible to construct a false ceiling from this.

With the panels 2 assembled together, the molten material 3 connects the circumferences of the panels 2 directly or indirectly, in a dotted or continuous manner. As a result, this melting material 3 begins to melt as soon as the room temperature rises to a predetermined value, and as a result, the panel of the false ceiling, indicated by reference numeral 2 in FIG. As the smoke is exhausted, the automatic sprinkler rad 4 of the fire extinguishing system 5 located above the detached panel 2 is activated.

Therefore, the water jet from the sprinkler is immediately sprayed onto the center of the fire through the opening formed in the false ceiling l by the separation of the panel 2.

If the melting material 3 is of adhesive type, it may be made into a thin layer to connect the panels 2 directly or indirectly, or it may be made into a band of an appropriate width and attached to the edge of the panel 2. These panels 2 may be connected with a fixed interval between them.

Furthermore, depending on its properties, it may be used as a device for mechanically fixedly connecting the panels 2 directly or indirectly to the molten material 3, at a specific point on the periphery of the panel 2, or over the entire periphery. It is also possible to configure

Specifically, the melting material 3 is formed into a clip shape and these clips are inserted into the panel 2, or
It can be fixed to the periphery of the panel 2 by clamping.

Next, another embodiment of the present invention will be described.

In this alternative embodiment, the molten material 3 is constructed in the form of a thread, and the panels 2 are connected to each other by sewing this thread, or alternatively, the molten material 3 in the form of a thread is applied to the sheets constituting the false ceiling l. Formed integrally with the material.

That is, while configuring the molten material 3 in the form of a thread in this way,
Part or all of the sheet material constituting the false ceiling l is made into a mesh shape. In this case, at least the weft portion of the mesh-like sheet material is constituted by the meltable material 3, and these plurality of meltable wefts are separated from the non-meltable thread material constituting the adjacent panel 2. so that

The sheet of elastic material that is divided into the plurality of panels 2 and forming the false ceiling l can be of fairly large dimensions, but it goes without saying that in determining the dimensions the molten material that connects them to each other It is necessary to consider the strength of 3.

On the other hand, as means for supporting this false ceiling l, it is also possible to support it with a support structure made of wires or cables provided separately, or to form this support structure integrally with the elastic material. It will be done.

Further, the color of the connecting portions of the peripheral portions of the panels 2 may be matched to the color of the elastic sheet material constituting the false ceiling 1, or the opposite color may be used to make this false ceiling 1, for example, the first and second It is also possible to form a check pattern as shown in FIG.

That is, the specific shape and other configurations of the panel 2 are as follows:
It can be arranged very freely depending on technical, mechanical, or even aesthetic needs. For example, in the one shown in FIG. 4, a plurality of square panels 2 are arranged in a zigzag pattern. ing.

The false ceiling 10 of the present invention can be manufactured from sheet material formed as a very long strip 6, for example as shown in FIG. In this case, the strip 6 has a plurality of transverse lines 7, each made of molten material, at regular intervals in its longitudinal direction.

Then, a plurality of strips 6 are stretched in parallel to form the false ceiling 1. As a result, one of the horizontal wires 7 will melt due to the rise in temperature associated with the fire outbreak, and that part of the false ceiling will surely fall off.

It is thus possible to form a canopy by connecting these strips 6 at their longitudinal edges to each other by means of molten material.

Furthermore, as mentioned above, when forming the sheet material into a belt shape, it is preferable to form the belt material 6 from a knit material. In other words, in this case, each of the meltable horizontal lines 7 is formed of a meltable yarn. It is formed by weaving one or more of the weft sections of the stitch.

In the embodiment shown in FIGS. 5 and 6, a plurality of different panels 2 constituting the false ceiling 1 are constructed as longitudinal strips of elastic material, the strips having ends at each end. 1'l'' and are horizontally juxtaposed to each other, forming, as a whole, one flat surface of sufficiently large dimensions to be able to effectively hide the superstructure of the building.

These elastic sheet-like strips are formed from fiber or paper sheet materials, or woven or knitted materials.

The strips are also assembled by being connected to each other at their respective longitudinal ends by gluing, mechanically fixing, etc. by means of a suitable type of molten material 3.

Furthermore, the false ceiling 1 with a large surface area may be widened by its other ends 4 and 5, ie laterally widened, and the connecting wire made of the melted material 3 can be fixed thereto.

In the case of the false ceiling 1 with the above configuration, the center of the fire 6
If a temperature rises below this false ceiling, the melting due to the heat associated with the fire will be concentrated at the connection line 3 due to the structural stress applied to each strip, resulting in a very large opening 7°. It was confirmed that smoke generated from the fire was discharged to the upper part of the building through this opening 7' and that the heat sensor was activated. These thermal sensors then start the automatic sprinkler 4 and activate the sprinkler 4.
A water jet 8 discharged from the fire center 6 was directed to the fire center 6 through the opening 7' formed in the false ceiling l.

The sheet material constituting the panel has sufficient elasticity to form a large opening when the connecting wire made of a low melting point material melts, taking into account initial assembly stress. It is preferable.

The panels 2 forming the longitudinal strips may be of considerable width, for example of the order of 2 to 3 metres. In this case, the strips 9 are longitudinally juxtaposed and separated from each other by a width of 9 degrees at regular intervals, as shown in FIG. It has a wire 10 made of a plurality of low melting point materials.

A very long strip 9 of this kind is preferably formed by knitting a refractory material, the fusion line IO of which
When the strip 9 is manufactured from a low melting point material, it is composed of one or more warp threads of knitted stitches.

According to the above method, it is possible to easily manufacture the band material 9 having a predetermined elasticity in the warp and weft directions of the stitches. If these strips 9 having such long lengths and considerable widths are formed into rolls, it becomes possible to quickly install the false ceiling 1.

Furthermore, in this case, the false ceiling may be formed by simply arranging the plurality of strips 9 having a considerable width constituting the false ceiling 1 in a horizontal direction without connecting them to each other by connecting lines. good. At this time, the band material 9 made of knit material is provided with sufficient elasticity in the longitudinal and lateral directions in advance, so that when the connecting wire 10 is melted, the elasticity in the longitudinal and lateral directions causes the panel 11 to is constructed so that it contracts in its width direction to form a sufficiently large opening for smoke exhaust and sprinkler water discharge.

[Brief explanation of the drawing]

1 is a perspective view of a false ceiling according to the present invention; FIG. 2 is a perspective view showing a state in which one of the panels constituting the false ceiling shown in FIG. 1 has been separated due to an outbreak of fire; FIG. 4 is a perspective view showing an example of a panel constituting the false ceiling of the present invention, FIG. 4 is a perspective view showing a modification of the false ceiling, and FIG. 5 is a perspective view showing another modification of the false ceiling. , FIG. 6 shows a modified example of the false ceiling shown in FIG. 5, and is a perspective view showing the state of this false ceiling in the event of a fire, and FIG. 7 shows a modified example of the false ceiling shown in FIG. It is a perspective view showing the constructed false ceiling. 1... False ceiling, 2, 6.9... Sheet material, 3.7.10... Melting means.

Claims (1)

[Claims] 1. A false ceiling consisting of a plurality of sheets of material connected to each other by means of fusing. 2. The false ceiling according to claim 1, wherein the melting means assembles the plurality of sheet materials together by gluing the peripheral portions of the sheet materials. 3. The false ceiling according to claim 1, wherein the melting means is configured as a thread material that connects the peripheral portions of the plurality of sheet materials. 4. The false ceiling according to claim 1, wherein the melting means is configured as a clip that fixes the peripheral portions of the plurality of sheet materials and assembles the sheet materials together. 5. The false ceiling according to any one of claims 1 to 4, wherein the sheet material is formed as a band material, and the band material has elasticity. 6. Claims 1 to 6, wherein the sheet material is partially or entirely made of a mesh-like fibrous material, and the weft of the mesh portion of the fibrous material is made of the melting means. The false ceiling described in any of 5. 7. The sheet material is formed as a very long strip having a plurality of lines of meltable material regularly spaced laterally thereof, and the plurality of these strips are
7. False ceiling according to claim 1, characterized in that they are juxtaposed to each other with or without fusible connecting lines. 8. the sheet material is formed as a very long strip;
Any one of claims 1 to 7, characterized in that the strip has at least one, preferably a plurality of fusion wire means distributed in its longitudinal and width directions. False ceiling as described in. 9. Each of the band materials is formed of a knit material, and the longitudinal line of the melting means connecting the plurality of panels is a warp portion of a stitch formed by knitting a thread material made of a low melting point material. The false ceiling according to claim 8, characterized in that it is constituted by one or more of the above. 10. The false ceiling according to any one of claims 5 to 9, wherein the plurality of strips are arranged in an expanded state. 11. The false ceiling according to claim 10, wherein the plurality of strips in the unfolded state are juxtaposed with each other with or without a melting means.