The present invention relates to a respirator hood, and, more particularly, to a respirator hood that fits comfortably over the head of a wearer and provides for efficient delivery of air to the interior of the hood and into the breathing zone of the wearer.
In various industries and manufacturing environments, a respirator hood is worn in combination with a positive pressure air source to protect against respiratory hazards, such as those found in pharmaceutical operations and healthcare facilities. Regardless of the specific application for which the respirator hood is designed, it commonly includes an integral bib or shroud or a neck cuff of some kind, an internal suspension means, a face shield or some form of transparent lens in a front opening defined by the hood, and a port for connection to a positive pressure air source.
However, because air is simply forced into the hood in most constructions, there is no efficient delivery of air to the interior of the lens and into the breathing zone of the wearer. Furthermore, since respirator hoods are commonly constructed of a flexible material, such as that marketed and distributed by E.I. duPont de Nemours and Company of Wilmington, Del. under the trademark Tychem®, the introduction of air into the interior of the hood has an inflating or ballooning effect that causes the hood to rise up relative to the head of the wearer.
It is therefore an object of the present invention to provide a respirator hood that ensures for efficient delivery of air to the interior of the hood and into the breathing zone of the wearer.
It is another object of the present invention to provide a respirator hood that prevents the ballooning and “rising up” of the respirator hood relative to the wearer, but without the need for cumbersome and uncomfortable suspension systems common in the prior art.
These and other objects and advantages of the present invention will become apparent upon a review of the following description and appended claims.
The present invention is a respirator hood that fits comfortably over the head of a wearer and provides for efficient delivery of air to the interior of the hood and into the breathing zone of the wearer. A hood made in accordance with the present invention is designed to fit over and around the head of a wearer and defines a front opening in which a transparent lens is received to protect the face of the wearer without obstructing vision. Air is provided through an inlet and is directed into a reservoir within the hood. From this reservoir, air is distributed to an inflatable neck cuff and one or more overhead channels that provide for efficient delivery of air to the interior of the hood and into the breathing zone of the wearer.
The neck cuff is positioned at the lower portion of the hood and substantially circumscribes the opening through which a wearer inserts his head into the hood. Incoming air inflates the neck cuff. Since there is no exit or outlet from the neck cuff, it remains inflated, thus causing the neck cuff to exert maximum sealing pressure against the wearer's neck and also prevents the hood from rising up relative to the wearer's head due to the upward forces resulting from the introduction of air into the interior of the hood.
Air is also directed from the reservoir into one or more overhead channels that provide for efficient delivery of air to the interior of the hood and into the breathing zone of the wearer. In one exemplary embodiment, and as further described herein, the hood is provided with three channels, although fewer or more channels could be incorporated into the hood without departing from the spirit and scope of the present invention. By providing multiple overhead channels, as opposed to a single, unitary channel, movement of the hood due to the air flow from the rear of the hood to the front of the hood is minimized. Specifically, by providing multiple overhead channels, there is not a significant extension of the channels into the interior of the hood, increasing headroom and reducing the likelihood that movement of the hood would cause the lens to be pushed against the wearer's face.
Lastly, it is contemplated that a hood made in accordance with the present invention could be provided with an integral exhalation valve that is designed to open and place the interior of the hood in fluid communication with the atmosphere should the air pressure within the hood exceed a predetermined value.
a is an enlarged perspective view of the exhalation valve illustrated in
The present invention relates to a respirator hood, and, more particularly, to a respirator hood that fits comfortably over the head of a wearer and provides for efficient delivery of air to the interior of the hood and into the breathing zone of the wearer.
Referring now to
Referring now to
Furthermore, as illustrated in
As mentioned above, air is also directed from the reservoir 14 into one or more overhead channels 20 that provide for efficient delivery of air to the interior of the hood 10 and into the breathing zone of the wearer. In the exemplary embodiment illustrated in
As mentioned above, the hood 10 is preferably provided with three channels 20. By providing multiple overhead channels 20, as opposed to a single, unitary channel, movement of the hood 10 due to the air flow from the rear of the hood 10 to the front of the hood is minimized. Specifically, if there were only a single channel, there would be a significant distance between the interior surface of the hood 10 and the section of non-rigid material 21 when inflated. In other words, the cross-sectional area of the channel would be quite large and would extend quite far into the interior of the hood 10, reducing the available headroom within the interior of the hood 10. By providing multiple overhead channels 20, there is not such a significant extension of the channels into the interior of the hood 10, increasing headroom and reducing the likelihood that movement of the hood 10 would cause the lens 11 to be pushed against the wearer's face.
Lastly, it should be noted that since there is no exit or outlet from the inflatable neck cuff 14, air is vented from the interior of the hood 10 between the inflatable cuff 14 and the neck of the wearer. Alternatively, as illustrated in
Furthermore, it should be understood that the exhalation valve 24 could be positioned in various other locations without departing from the spirit and scope of the present invention, provided that the exhalation valve 24 serves to relieve pressure from the interior of the hood 10 when air pressure within the hood 10 exceeds a predetermined value. For example, the exhalation valve 24 could be located in a side portion of the hood 10, in a lower portion of the hood 10 near the neck cuff 16, or adjacent the lens 11. Furthermore, multiple exhalation valves 24 could be incorporated into the hood 10 without departing from the spirit and scope of the present invention.
It will be obvious to those skilled in the art that further modifications can be made to the embodiments described herein without departing from the spirit and scope of the present invention.
The present application claims priority to U.S. Provisional Application Ser. No. 60/504,292 filed Sep. 18, 2003, the entire disclosure of which is incorporated herein by reference
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