The present invention relates to oxygen masks, and more particularly relates to oxygen masks used with military aircraft pilot helmets.
Currently standard flight helmets for fixed wing and rotor aircraft use the same clip on oxygen mask as found on fighter helmet applications. This provides oxygen/hypoxia protection but no “smoke” protection. Smoke protection is usually considered to include some form of sealed eye protection with an integral positive pressure or other means for keeping contaminants out, in addition to respiratory protection. Flight helmets come in a variety of sizes and designs, thus making the application of a single mask to a variety of designs a difficult problem. This represents a significant disadvantage in light of the large number of different flight helmet designs that currently exist.
For example, one such conventional smoke mask that currently will fit within and interact with a flight helmet has a design that requires that the flight helmet and front opening of the flight helmet be large enough to allow the face seal of the smoke mask to fit inside the flight helmet for direct contact with the wearer's face. This design is constrained to fit completely within the flight helmet to contact the face, limiting the field of view available to the wearer.
Current full face oxygen masks are also typically designed to fit on the heads and facial features of about 5 to 95 percent of pilots and crew, but these masks typically will not fit or interact with a pilot or crew member additionally wearing a flight helmet for protection.
Thus, there is a need for an oxygen mask which provides an adequate breathing gas environment and protection from smoke and debris which can be adapted for use with a wide variety of pilot helmets. The present invention fills these and other needs.
Briefly, and in general terms, the present invention provides for a full face flexible oxygen mask for use with flight helmets, wherein the mask includes an elastic face seal that has an oronasal cone that seals around the nose and mouth to provide the maximum required contaminant and leakage protection, and flexible sealing flaps along the perimeter of the face seal to seal against the surface of a flight helmet, rather than sealing to the face of the wearer. The mask face piece has two large sealing surfaces or channels down each side of the mask that overlap and flex as necessary to adapt to seal to a variety of flight helmet designs and exterior surfaces currently being used. The top of the face seal has inner and outer sealing flaps that work together to seal the exposed face of the wearer visible between the sides of the flight helmet. In one variant, the sealing flaps may have a chamber inside that may be at least partially inflated to enhance the sealing properties of the sealing flaps. By eliminating the constraint of fitting completely within the flight helmet perimeter to contact the face of the wearer, and providing flexible sealing flaps to adapt to seal with a variety of sizes and types of flight helmets, allowing the use of larger size flight helmets, the full face flexible oxygen mask of the invention avoids limitations upon the field of view available to the wearer that are characteristic of face masks that are constrained to fit completely within the flight helmet perimeter to insure sealing contact with the face of the wearer.
These and other aspects and advantages of the invention will become apparent from the following detailed description and the accompanying drawings, which illustrate by way of example the features of the invention.
As is illustrated in the drawings, the invention is embodied in a full face flexible oxygen mask for use as a smoke mask with flight helmets, that can adapt to fit to most or all flight helmets and provide smoke/eye protection along with oxygen. The full face flexible oxygen mask is embodied in a flexible, full face coverage mask for use by aircraft flight crews in which a flexible lens is sealingly molded into the face seal, or is formed with the face seal as a single unit. The mask incorporates an inflatable harness which is inflated by the breathing oxygen regulated by a regulator incorporated into the face mask. In one aspect of the full face flexible oxygen mask, the inflatable harness is dimensioned so as to fit over the circumference of the helmet. The mask also provides for purging of the interior of the flexible lens by gas from the regulator in order to retard fogging and other obscuration of the view out of the lens by the wearer. The entire assembly is capable of being rolled up into a relatively small package, which facilitates its installation within the limited available space readily at hand to the seated crew member on the flight deck. An interactive full face mask according to the invention, stowed in a ready position for quick donning, could readily be mounted on Air Force, Naval, Army, Coast Guard type support craft such as the E-2C, C-2, P-3, and C130, for example.
Referring to
The lower forward portion of the face seal includes an oxygen supply regulator 16 removably attached to the lower forward portion 17 of the mask to provide oxygen in diluted, 100%, positively pressurized forms to the user. The regulator supplies breathing oxygen to the wearer through ports internal to the lower forward portion of the face seal, and also supplies oxygen or other breathing gas mixtures to an inflatable harness 18 such as inflatable tubes 18a and 18b, designed to encircle the helmet, and connected to the breathing gas regulator and the face seal via suitable gas passages and connectors in the mask. As is illustrated in
The use of the flexible lens in concert with the elastomeric face seal of the invention serves to improve the ability of the mask to seal out toxic or vision impairing gases. These improved face sealing characteristics also improve the oxygen consumption performance of the mask, as there is less leakage over a wider variety of face configurations. The oxygen supply for the mask is provided by an oxygen supply tube 28 connected to regulator. In order to facilitate communication, the mask may also incorporate a microphone (not shown) which can be connected to the aircraft communication system by electrical wiring 30, which may be concurrently routed with the oxygen supply tube.
Referring to
The mask fits to a variety of helmet designs with slightly different dimensions and fits on the user's head. The flexibility of the frame and lens allow the mask to adapt or conform the helmet surfaces until the oronasal cone and face seal contact the recessed user's facial features. It will be appreciated that by eliminating the constraint of fitting completely within the helmet to contact the face of the wearer, the full face flexible oxygen mask of the invention avoids the limitations of field of view that are characteristic of face masks that are constrained to fit completely within the flight helmet perimeter to insure sealing contact with the face of the wearer.
It will be apparent from the foregoing that while particular forms of the invention have been illustrated and described, various modifications can be made without departing from the spirit and scope of the invention. Accordingly, it is not intended that the invention be limited, except as by the appended claims.
This application is a U.S. national phase of PCT/US03/30606, filed 24 Sep. 2003, which is based on provisional application Ser. No. 60/414,901, filed Sep. 30, 2002.
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/US03/30606 | 9/24/2003 | WO | 00 | 5/10/2004 |
Publishing Document | Publishing Date | Country | Kind |
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WO2004/030766 | 4/15/2004 | WO | A |
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