Containment device comprising a dry curtain

Abstract

A containment device including a dry curtain, adapted to be deployed for the containment or re-containment of a discharge area, such as an opening, e.g. a door, in response to an explosion. The device includes a ballast bar in the lower portion of the curtain, the ballast bar including cylinders of high-density foam alternated with cylinders of compressible low-density foam.

Claims

1. A containment device comprising a dry explosive gas containment curtain designed so as to deploy from a folded position to an extended position in response to a blast in a room or building so as to contain or recontain at least explosive gaseous discharge from a discharge zone made of an opening of said room or building, the containment device further comprising a ballast bar in a lower part of the curtain, wherein said ballast bar, providing a mass at a bottom of the curtain, includes an alternation of first cylinders, said first cylinders being made of a high density foam and of second cylinders, said second cylinders being made of compressible low density foam, and wherein said first and second cylinders effect conforming of the dry curtain to a ground surface and impede gases of the blast from escaping under the dry curtain.

2. The containment device as claimed in claim 1, wherein the first cylinders have a length of 100 mm to 300 mm.

3. The containment device as claimed in claim 1, wherein the second cylinders have a length of 20 mm to 60 mm.

4. The containment device as claimed in claim 1, wherein said first and second cylinders are threaded onto a cord.

5. The containment device as claimed in claim 1, wherein the second cylinders are designed to deform so that the ballast bar conforms to a shape of an obstacle on the ground, the first cylinders therefore resting against the shape of the obstacle.

6. The containment device as claimed in claim 1, wherein a diameter of the ballast is 60 mm to 100 mm, the first and second cylinders being sized so as to conform to an obstacle 50 mm to 150 mm thick.

7. The containment device as claimed in claim 1, comprising horizontal stiffeners evenly distributed in the curtain.

8. The containment device as claimed in claim 7, wherein the horizontal stiffeners are aluminum profile sections.

9. The containment device as claimed in claim 7, wherein strips of fabric for retaining the horizontal stiffeners are one or more of stitched and bonded locally to a fabric of the curtain, the horizontal stiffeners being at least partially disposed between the strips and the curtain.

10. The containment device as claimed in claim 9, wherein the strips of fabric supporting the horizontal stiffeners stop in line with a fixed frame of the opening that is to be recontained, leaving the horizontal stiffeners free beyond that.

11. The containment device as claimed in claim 10, wherein the horizontal stiffeners rest against the fixed frame over 50 mm to 100 mm, and the curtain rests against the fixed frame over 150 mm to 200 mm.

12. The containment device as claimed in claim 7, wherein a length of the horizontal stiffeners is such that said horizontal stiffeners press the curtain against lintels of the opening that is to be recontained when a room that is to be contained returns to a state of depression after the blast.

13. The containment device as claimed in claim 12, wherein the horizontal stiffeners are shorter than a width of the curtain such that flexibility of strips of curtain beyond the horizontal stiffeners is maintained, said strips of curtain beyond the horizontal stiffeners acting as a seal against the lintels or surround of the opening when the room that is to be contained returns to a state of depression after the blast.

14. The containment device as claimed in claim 7, wherein the horizontal stiffeners are stitched every 400 mm to 600 mm over a height of the curtain.

15. The containment device as claimed in claim 1, wherein the curtain comprises a glass weave and a PTFE coating.

16. The containment device as claimed in claim 1, wherein the low density foam has a density of 17 to 20 kg/m3.

17. The containment device as claimed in claim 1, for which the high density foam has a density of 25 to 30 kg/m3.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) Other features and advantages of the disclosed embodiment will become apparent from reading the following description of some nonlimiting examples which is accompanied by the drawings which depict:

(2) FIG. 1 is a perspective view of a containment device according to the disclosed embodiment, deployed;

(3) FIG. 2 is a perspective view of one aspect of a ballast bar of the device of FIG. 1;

(4) FIG. 3 is a perspective view of the ballast bar of FIG. 2 during operation;

(5) FIG. 4 is a perspective detail of one example of a stiffener according to one aspect of the disclosed embodiment;

(6) FIG. 5 is a perspective detail of the insertion of the stiffener of FIG. 4;

(7) FIGS. 6A and 6B are views from above of a curtain of the device respectively at ambient pressure and in a state of depression.

DETAILED DESCRIPTION

(8) The disclosed embodiment provides a device comprising a dry curtain arranged in such a way as to be able to contain or recontain a discharge zone, for example a door, in response to the blast of an explosion. The device of the disclosed embodiment is produced in such a way as to deploy rapidly and to be unlikely to be found to be defective following an explosion.

(9) The material of the curtain is chosen according to the chemical resistance performance required but is typically made up of a woven fabric coated on both sides with one or more layers of one or more sealing materials, the weave also being equipped with horizontal stiffeners distributed over the entire height of the curtain.

(10) FIG. 1 depicts the curtain 1 deployed along the surround of a door.

(11) The curtain has deployed from a modular box 2 and comprises a compensation seal 5 which rests on the ground.

(12) The curtain storage box 2 is made up of a plurality of juxtaposed modules 2a, 2b, 2c, 2d, the plurality of modules comprising modules 2b referred to as active modules which are provided with curtain retaining and release means which will foe detailed further on, and modules referred to as passive modules 2a, 2c, 2d which do not have said means for retaining and releasing the curtain 1.

(13) In the event of an explosion, the fact that the box is made in the form of modules sized to withstand explosions allows the box to deform if the door lintel deforms.

(14) For a door measuring 4 m wide and a door height of 4 m, assuming that the curtain overhangs the fixed frame by 50 cm on each side, a box in the form of a parallelepiped measuring approximately 0.80.65 m is required.

(15) The suitable number of modules for this length is selected in the knowledge that use is made of two end modules 2a and two active modules 2b, as many additional passive modules 2c as required being positioned between the active modules.

(16) A small explosion fixed for example at 40 g of TNT, located on the ground 5 m away from the door will generate a dynamic overpressure spike of around 7000 Pa on the blow-out panel, and this leads to a dynamic stress spike of 5600 N.

(17) The time taken for the curtain to fail into place may be estimated at under one second because its deployment corresponds approximately to a freefall from a height of 4 m.

(18) This is a freefall and no guide is produced on the sides of the opening, as such guides will do nothing but slow the fall of the curtain or even block it in the event of deformation following the explosion.

(19) The curtain comprises a ballast bar inserted into a fold of the curtain 5 that forms a coating as depicted in FIG. 1.

(20) The ballast bar 4 according to FIG. 2 is designed to provide sufficient mass for the curtain to deploy correctly and to encourage sealing at the interface.

(21) For a curtain weighing 25 kg, with the dimensions given above, a ballast bar weighing, for example, of the order of 5 kg will help the curtain to fall.

(22) The bar in the area of contact between curtain and ground, be deformable in order to minimize the leakage area in the event of debris generated by the explosion being trapped in the plane of closure of the curtain.

(23) The ballast consists of a cord 44 made of polypropylene or some other strong material, for example with a diameter of 30 mm, onto which an alternation of medium or high density foam cylinders 41, for example 200 mm in length, and compressible and for example open-cell low-density foam cylinders 42, for example 40 mm in length are threaded. The low density foam is, for example, a polyether. It advantageously has a density of 17 to 20 kg/m.sup.3.

(24) The high density foam is, for example, a polyurethane foam. Its density is advantageously from 25 to 30 kg/m.sup.3.

(25) Each foam cylinder is bonded to a section of steel tube which provides the ballast and which allows easier use of the cord. Now the overall mass of the ballast in the example considered is around 8 to 12 kg.

(26) As depicted in FIG. 3, if an obstacle 101, for example debris caused by the explosion, lies in the closure plane, the low-density cylinders 42a, 42b, 42c, 42d preferably deform to allow the weighted casing to conform to the shape of the obstacle, the cylinders 41 then hugging the obstacle.

(27) The diameter of the ballast inserted into the casing is, for example, 80 mm and the low density and high density cylinders are sized to be able to hug an obstacle with a characteristic size of 100 mm.

(28) Stiffeners 10 are uniformly distributed in the curtain 1 and the stiffeners are, for example, such as the extruded aluminum profile section of FIG. 4 which offers good stiffness for a low mass.

(29) These stiffeners are needed because the containment zone is at a depression of 50 to 100 Pa under normal operation of the building in the case of a building in which chemical or pollutant products are handled. The stiffeners allow the curtain to be pressed firmly against the surround of the opening when the building returns to a state of depression after the explosion.

(30) It is this depression which presses the curtain firmly against the door and which requires the curtain to be rigid.

(31) According to FIG. 5, in order to position this profile section, a strip of fabric 11 is stitched and/or bonded locally to the fabric of the curtain 1, for example leaving an opening at the ends of the strip, and the profile section is slipped in through the opening between the two fabrics.

(32) As depicted in FIG. 6A, the length of the profile sections 10 is such that they press the curtain 1 against the lintels 20 of the door.

(33) These profile sections are, however, shorter than the width of the curtain so that strips of curtain beyond the profile sections maintain their flexibility and can act as a seal against the wall under the effect of the depression. Thus, the curtain free on the lateral sides protrudes beyond the edges of the surround and with no lateral guidance provided the curtain simply hangs along the opening.

(34) According to FIG. 6B, under the effect of the creation of a depression D in the room that is to be recontained, the suction of the curtain causes the stiffeners 10 to deform. In order for the ends of the stiffeners not to detach the curtain from the fixed frame, the casings 11 supporting the stiffeners stop in line with the fixed frame, leaving the stiffeners free beyond that.

(35) Thus, as the stiffeners flex, their ends move away from the curtain which remains pressed firmly against the fixed frame.

(36) By way of example, provision is made in the case of the door described hereinabove for the stiffeners to press against the fixed frame over 100 mm and for the curtain to press against the fixed frame over 200 mm.

(37) Depending on the depression that is to be withstood, the aluminum profile section curtain stiffeners are, for example, stitched and/or bonded every 500 mm over the height of the curtain.

(38) The curtain material is chosen according to the chemical resistance performance required but typically consists of a woven fabric coated on both sides with one or more layers of one or more sealing materials, the weave also being provided with the horizontal stiffeners distributed over the entire height of the curtain.

(39) The material with which the curtain is coated needs to be a material that is chemically compatible with the gases, aerosols and dust given off in the explosion, namely a material that does not degrade in contact with these elements.

(40) The material is, for example, a material containing glass fiber and PTFE or even an NBC (nuclear, bacteriological, chemical) or even NRBC (nuclear, radiological, biological, chemical) qualified material.

(41) One example may be the material supplied by the Saint-Gobain company under the trade name Coretech Shelterguard 1450.

(42) The weave of the curtain may notably be created using aramid or glass fiber.

(43) The disclosed embodiment defined by the claims is not restricted to the examples given and notably applies to other openings and not just doors.