System and method for protection against nuclear, biological and chemical (NBC) contamination

The invention provides an NBC protection and decontamination system, having a space delimited by an enclosure, the enclosure having a clean air inlet port and an air outlet, a decontamination unit attachable to the outside of the enclosure, the decontamination unit having a plenum and a chamber separated from the plenum by an air flow laminator. The system also includes at least one air inlet valve communicating with the air outlet of the enclosure and leading to the plenum and to at least one air exhaust valve made in the chamber, spaced apart from the air inlet valve. An opening is provided for controlled passage between the enclosure and the decontamination unit, and also an opening in the decontamination unit, for controlling the passage between the unit and the outside. There is also provided an NBC protection and contamination method.

FIELD OF THE INVENTION

The present invention relates to a system for protection against nuclear, biological and chemical (NBC) contamination, and a method for providing effective flushing and decontamination of NBC agents.

BACKGROUND OF THE INVENTION

As is known, the need for collective protection has recently increased, due to the threat of military attacks and acts of terror using methods and components of chemical or biological warfare. The problem that a contamination-protected space is enclosed always exists; people have to be able to enter and leave a mobile shelter or tent without harming the atmosphere within. One method of solving this problem is to use shelters or protected spaces in which an airlock chamber serves as the entrance or exit. Such an airlock chamber should not only have airlock characteristics, but also should enable decontamination. All contamination adhering to persons and/or other elements entering the protected space must be flushed off as effectively as possible, thereby assuring that no contaminated air will enter the protected space.

To date, air-tight tents having an integrated airlock chamber have not provided effective decontamination within a short period of time. The decontamination method used in prior art shelters of this type is to push clean air into the airlock chamber on one side and to pass it through the airlock chamber, preferably diagonally, to leave the chamber via holes in the wall opposite to the air inlet. The disadvantages of this method are that the airflow has too much turbulence and the length of time needed for decontamination is too long. As a result, the use of such airlock chambers for decontamination is limited. Furthermore, the entrance procedures for using these chambers and their ability to accommodate large numbers of individuals, are also complicated.

DISCLOSURE OF THE INVENTION

It is therefore a broad object of the present invention to ameliorate the above-described and other disadvantages of prior art systems and to provide an NBC decontamination system and a method for protecting enclosed spaces against the penetration of contaminated, hazardous fluids and/or particles.

It is a further object of the invention to provide an airlock decontamination unit suitable for attachment to a wall of an enclosed space to be protected against the penetration of contaminated, hazardous fluids and/or particles.

Accordingly, the present invention provides an NBC protection and decontamination system, comprising a space delimited by an enclosure, said enclosure having a clean air inlet port and an air outlet; a decontamination unit attached or attachable to the outside of said enclosure, said decontamination unit having a plenum and a chamber separated from the plenum by an air flow laminator; at least one air inlet valve communicating with the air outlet of said enclosure and leading to said plenum and to at least one air exhaust valve made in said chamber, spaced apart from said air inlet valve; an opening, providing controlled passage between said enclosure and said decontamination unit, and an opening in said decontamination unit, providing controlled passage between said unit and the outside.

The invention further provides an NBC protection and decontamination system, comprising a space delimited by an enclosure constituted of walls and surfaces, the enclosure having at least one clean air inlet port and at least one air outlet; a decontamination unit attached or attachable to a wall of the enclosure, the decontamination unit having at least one air inlet communicating with the air outlet from the enclosure and at least one air exhaust valve spaced apart from the air inlet; the decontamination unit further having normally closed access openings to the enclosed space and to the outside, the arrangement being such that clean air flow within the space inside the enclosure is directed from one wall to an opposite wall in which the air outlet is located and air inside the decontamination unit is directed substantially from one end of the unit to the other end, so as to produce laminar air flow through the enclosed space and the decontamination unit.

The invention still further provides an NBC protection and decontamination method, comprising providing a system as claimed in claim1or claim21, directing air across the enclosed space towards the decontamination unit through at least one overpressure valve; entering the directed air into the plenum; producing a laminar airflow inside the chamber, and allowing air to exit from the chamber through at least one air exhaust valve.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS

Illustrated inFIG. 1is a system2according to the invention for improving protection against NBC contamination by fluids and/or particles in enclosed spaces. Shown is an enclosure4, which may be a collapsible tent or a similar structure having fluid-tight walls and surfaces made of flexible material, or an enclosure made of semi-rigid or rigid material or a combination of such materials. The enclosure generates a toxic-free area (TFA) or space6. The front wall of enclosure4is fitted with an airlock decontamination unit8and may also include a normally closed door10. Mechanically and chemically filtered air from the outside enters the TFA through one or more air inlet ports12and is guided, through tubes13, toward the upper portion of space6opposite the front wall where the airlock unit is situated. The clean air exits from tube13through a manifold14. Normally closed utility sleeves15, for the entry of various piping, such as electrical cables, water pipes, and the like, may also be provided.

Turning now toFIG. 2, airlock decontamination unit8is illustrated to a larger scale. Unit8includes a plenum16at its upper portion and a decontamination chamber18at is lower portion. Chamber18is accessed from the front and back through closable openings20,22, which are opened and closed, e.g., by means of zippers, magnetic flaps, Velcro® strips or tapes, or the like. Plenum16and chamber18are separated by a fluid laminator24, essentially composed of an array of small apertures26. The aim of the small apertures26of the laminator24is also to create an overpressure in the plenum to ensure laminar flow into the chamber. Further shown inFIG. 2are optionally adjustable over-pressure valves28and a safety valve30, all communicating with plenum16. The sum of the small apertures26are preferably less than 90% of the area of the air inlet of the overpressure valve or valves28. The amount of the air apertures26should advantageously be ten times higher than that of the valves28. Also, it is of advantage that the sum of the area of the openings26be more than 10% of the sum of the area of the opening of the air exhaust valves. Fluid exhaust valves32are distributed adjacent to the bottom or floor33of chamber18. The exhaust valves32can be made integral with, or affixed to, the floor33surface of decontamination unit8. Preferably the diameter of the opening of the exhaust valves32should be less than 10 mm. or a free space less than 70 mm2per opening.

As can clearly be seen inFIGS. 3 to 5, the configuration of decontamination unit8may vary in accordance with structural and/or aesthetic considerations. Hence, unit8may be triangular, as shown inFIGS. 1 and 2, rectangular (FIG. 3), semi-circular (FIG. 4), or polygonal (FIG. 5).

The operation of the system will now be described with reference to the figures.

Mechanically and chemically filtered clean air is entered into air inlet port12and propelled by pumping or suction through tube13to the upper portion of space6, where it exits through manifold14and flows in the direction of the arrows towards the wall opposite the manifold. The clean air then enters the plenum16through overpressure valves28, thus forming an overpressure in the volume of the plenum. The clean air is distributed throughout the volume of the plenum and enters decontamination chamber18through apertures26in laminator24. The air eventually exits chamber18through exhaust valves32.

The size of apertures26and the pattern of distribution are such that over-pressure air in the plenum produces a well-distributed, laminar airflow in the chamber from top to bottom. The sizes of the inlet and, in particular, the exhaust valves32, are chosen and can be adjusted so as to provide the desired laminar airflow, producing a satisfactory decontamination effect of persons and/or equipment located inside the chamber18. It is desired, inter alia, to achieve a more thorough decontamination at a shorter dwelling period of the air, e.g., a dwell/decontamination period of about 2–3 minutes, or even less.

Although the above-described embodiments refer to an enclosure4and a separate decontamination unit8, it should be understood that the enclosure4and unit8may have a common wall, in which a closable opening is made. Unit8may be attached to enclosure4by means of one or more zippers, or the like, or directly integrally made or permanently attached to the enclosure4, e.g., by welding.