Patent Grant
6845517
The present invention relates to garments and, more particularly, to protective garments having a vent such as a vented moisture barrier.
Protective or hazardous duty garments and garment sets are widely used in various industries to protect the wearer from various hazardous conditions, such as heat, smoke, cold, sharp objects, chemicals, liquids, fumes and the like. Each protective garment may include an outer shell layer, a thermal barrier or thermal liner located inside the outer shell, and a moisture barrier located inside the outer shell. The moisture barrier may be semi-permeable such that the moisture barrier is generally liquid impermeable and generally moisture vapor permeable.
The moisture barrier may be located inside the outer shell to block moisture from the ambient environment from passing through the garment, while allowing moisture vapor inside the garment to pass through the moisture barrier. However, although the moisture barrier may be generally permeable to moisture vapor to allow moisture vapor to pass therethrough, moisture vapor may still remain trapped inside the garment. In particular, under heavy work conditions the moisture vapor generated by the wearer (for example, by perspiration) may be generated at a rate greater than that which the moisture barrier can pass therethrough. Accordingly, there is a need for a protective garment with an improved system for enabling the escape of moisture vapor.
In one embodiment, the invention is a garment, such as a protective garment, which has a vented layer, such as a vented moisture barrier to allow moisture vapor to be vented out of the garment. In one embodiment, the invention is a protective garment including a generally continuous outer shell and a moisture barrier located generally inside of the outer shell such that when the garment is worn, the moisture barrier is located generally between the outer shell and a wearer of the garment. The moisture barrier includes at least one vent such that at least part of the air located inside the moisture barrier can be vented outside of the moisture barrier.
These and other objects and advantages of the present invention will be apparent from the following description, the accompanying drawings and the appended claims.
The coat 10 may include a pair of knit wristlets 30 which may be made of an aramid material and located at the distal end of each sleeve 18, 20. The coat 10 may also include a collar 32 of an aramid material attached to the back panel 12 and front panels 14, 16.
The coat 10 may include various layers through the thickness of the garment, such as an outer shell 40, a moisture barrier 42 located inside of and adjacent to the outer shell 40, a thermal liner or barrier 44 located inside of and adjacent to the moisture barrier 42, and an inner liner or face cloth 46 located inside of and adjacent to the thermal liner 44. The outer shell 40 may be constructed of a variety of materials, including a flame, heat and abrasion resistant material such as a compact weave of aramid fibers and/or polybenzamidazole fibers. Commercially available aramid materials include NOMEX and KEVLAR fibers (both trademarks of E.I. DuPont de Nemours & Co., Inc.), and commercially available polybenzamidazole fibers including PBI fibers (a trademark of Celanese Corp.). Thus, the outer shell 14 may be an aramid material, a blend of aramid materials, a polybenzamidazole material, a blend of aramid and polybenzamidazole materials, or other appropriate materials, and may have a weight of, for example, between about 6-10 oz/yd2.
The moisture barrier 42 and thermal liner 44 may be generally coextensive with the outer shell 40, or spaced slightly inwardly from the outer edges (i.e., the ends of the sleeves, the collar and the bottom edge) of the outer shell 40, to provide moisture and thermal protection throughout the coat 10. The moisture barrier 42 may include a semi-permeable membrane layer 50, which may be generally moisture vapor permeable but generally impermeable to liquid moisture. The membrane layer 50 may be made of or include expanded polytetrafluoroethylene (“PTFE”) such as GORE-TEX or CROSSTECH (both of which are trademarks of W. L. Gore & Associates, Inc.), polyurethane-based materials, neoprene-based materials, cross-linked polymers, polyamid, or other materials. The membrane layer 50 may have microscopic openings that permit moisture vapor to pass therethrough, but block liquids from passing therethrough. The membrane layer 50 may be made of a microporous material that is either hydrophilic, hydrophobic, or somewhere in between. The membrane layer 50 may also be monolithic and may allow moisture vapor transmission therethrough by molecular diffusion. The membrane layer 50 may also be a combination of microporous and monolithic materials (known as a bicomponent moisture barrier), in which the microporous or monolithic material can be layered or intertwined.
The membrane layer 50 may be bonded or adhered to a substrate 52 (
In the orientation illustrated in
The thermal liner 44 may be made of any suitable material which provides sufficient thermal insulation. In one embodiment, the thermal liner 44 may include a relatively thick (i.e. typically from {fraction (1/16)}″-{fraction (3/16)}″ thick) batting, felt or needled non-woven material 54 which can include aramid fiber batting (such as NOMEX batting), aramid needlepunch material, an aramid non-woven material, an aramid blend needlepunch material, an aramid blend batting material, an aramid blend non-woven material, or foam (either open or closed cell) materials. The batting 54 preferably traps air and possesses sufficient loft to provide thermal resistance to the garment 10. The batting 54 is typically quilted to the face cloth 46, and the thermal liner face cloth 46 may be a weave of a lightweight aramid material. Thus, either the batting 54 alone, or the batting 54 in combination with the face cloth 46, may be considered to be the thermal liner 44. In one embodiment, the thermal liner 44 may have a thermal protection performance (“TPP”) of at least about 20, or of at least about 35. The thermal liner 44 may be treated with a water-resistant material. The face cloth 46 may be designed to be the innermost layer of the garment 10, 12, and can provide a comfortable surface for the wearer and protect the batting 54 from abrasion by the wearer.
Each layer of the coat 10, and the coat 10 as a whole, may be designed to meets the National Fire Protection Association (“N.F.P.A.”) 1971 standards for protective firefighting garments (“Protective Clothing for Structural Firefighting”). The NFPA standards specify various minimum requirements for heat and flame resistance and tear strength. For example, in order to meet the NFPA standards, an outer shell 40 of a firefighter garment must be able to resist igniting, burning, melting, dripping and/or separation at a temperature of 500° F. for at least five minutes. Furthermore, in order to meet the NFPA standards, all combined layers of the garment 10 must provide a thermal protection performance rating of at least 35.
The moisture barrier 42 and thermal liner 44 may be permanently attached to each other about their peripheries (or about their peripheries and interior), such as by stitching, so that the moisture barrier 42 and thermal liner 44 function as a unitary component of the garment 10. In this case, the moisture barrier 42 and thermal liner 44 may be referred to together as the inner liner 60 of the garment 10. In one embodiment, the moisture barrier 42 and thermal liner 44 can be combined into a removable inner liner 60. For example,
Various layers of the garment 10 may be vented to allow the rapid expulsion of air and/or moisture vapor from inside the garment 10. For example, as shown in
As noted above, the vent 70 may be formed by overlapping the upper 72 and lower 76 portions of the moisture barrier 42. The upper 72 and lower 76 portions of the moisture barrier 42 may then be coupled together in a variety of manners. In one embodiment, the upper 72 and lower 76 portions are coupled together at a plurality of spaced locations to form discreet spaced vents 70′. For example, as shown in
Each stitched tack 80 may include a few stitches or a small stitch line that extends through the overlapping portions of both the upper 72 and lower 76 portions of the moisture barrier 42 to coupled the upper 72 and lower 76 portions together. Each pair of stitched tacks 80 may include two generally vertically spaced stitched tacks, with the upper stitched tack 80a (
The stitched tacks 80 couple the upper 72 and lower 76 portions together to maintain the upper 72 and lower 76 portions in their desired orientation. For example, in the embodiment illustrated in
Each of the stitched tacks 80 may be covered with a sealant, such as a tape 82.
In one embodiment, the sealant is made of the same materials as the membrane 50 of the moisture barrier 42 with an adhesive applied thereto. Thus, the tape 82 may be, for example, a PTFE film, although the sealant can take a variety of other forms, includes sealants applied in a liquid form and cured into a solid. As shown in
The vent 70 formed by the upper 72 and lower 76 portions of the moisture barrier 42 enables relatively large volumes of air to be expelled through the vent 70, thereby enabling moisture vapor-laden air located inside the inner cavity 54 of the garment 10 to be expelled, such as by convection. The air in the inner cavity 54 of the coat can be expelled through the vent 70 by various forces, including by the movement of the wearer. For example, natural movements of the wearer, such as lifting, walking, crawling, etc. will cause billowing and deflation of the garment 10, thereby forcing air through the vent 70. The moisture-laden air may thereby be moved from the inner cavity 54 through the vent 70 and into the space between the outer shell 40 and moisture barrier 42. In this case, the moisture-laden air is spaced away from the thermal barrier 44, and the moisture-laden air can then work its way outside the garment 10. Thus, the vent 70 and outer shell 40 may be arranged such that there is generally no direct path from the outside of the garment 10 through the outer shell 40 to the inner cavity 54 or to inside of the moisture barrier 42.
Although the upper 72 and lower portions 76 may at least partially overlap, they need not necessarily overlap to form the vent 70. For example, a slit may be formed in the moisture barrier 42, and all that is required is that a slit, opening, hole or other vent be formed in the moisture barrier to allow air located inside the inner cavity 54 to be carried outside the moisture barrier 42. Furthermore, the vent 70 need not be a continuous slit, opening, hole or the like. The vent may be or include a plurality of discrete openings, such as those included in a mesh material or the like. However, the overlapping nature of the moisture barrier 42 may help to keep liquid moisture, such as liquid from the ambient environment, outside the inner cavity 54. The upper 72 and lower 76 portions may overlap by nearly any desired length, such as greater than about ½″, between about ½″ and about 6″, or about 4″. The vent 70 may be located at nearly any desired location along the vertical height of the coat 10, but may be located below the armholes of the garment.
As noted above, the stitched tacks 80 couple the upper 72 and lower 76 portions of the moisture barrier 42 together to maintain the upper 72 and lower 76 portions in their desired orientation. The stitched tacks 80 may extend generally horizontally, generally vertically, or in some other direction. Furthermore, the stitched tacks 80 may extend a relatively short distance along the height or width of the coat 10 or along the overlapping portions to ensure that the vent 70 or vents 70′ remain open to ensure the free flow of air therethrough. Furthermore, because the vent 70 may extend around the entire perimeter or circumference of the moisture barrier 42 and/or garment 10, the entire inner cavity 54 can be effectively vented.
In some cases, it may be desired to switch the orientation of the moisture barrier 42 and the thermal barrier 44. For example, as shown in
Furthermore, the outer shell 40 and/or the thermal liner 44, as well as any other layers of the garment 10 besides or in addition to the moisture barrier 42, may also be vented. The outer shell 40, thermal liner 44, and other layers can be vented by overlapping the portions of the garment, as outlined above for the moisture barrier 42, or can be vented in various other manners (such as forming slits, openings, etc.). Furthermore, any one of the layers, or each of the layers, or various combinations of the layers may be vented as desired.
Additionally, the garment 10 need not necessarily include each of the outer shell 40, moisture barrier 42 or thermal liner 44. For example, the garment 10 may include only an outer shell 40 and moisture barrier 42, either of which or both of which may be vented. The garment 10 may also include only an outer shell 40 and a thermal liner 44, either of which or both of which may be vented. The garment 10 may also include only an outer shell 40 and a combined moisture barrier/thermal liner, either of which or both of which may be vented.
As shown in
Furthermore, it should be understood that the vented layer or layers of the present invention is not limited to garments in the form of a turnout coat or pants. Although a coat 10 and pants 88 are illustrated herein, it should be readily apparent to one skilled in the art that the arrangement of the various layers of the garments shown and described herein is applicable to various other garments beyond the coat 10 and pants 88 specifically shown herein. The vented arrangement may also be applied to the jumpsuits, parka-style firefighter coats, coat and pant combinations, EMS garments, USAR (Urban Search And Rescue) garments and the like, without departing from the scope of the invention.
Various methods of assembling the garments disclosed herein may be used. In one embodiment, the material for the outer shell 40 is supplied in roll form, and patterns (i.e., in the case of the coat 10, patterns for the back panel 12, panels 14, 16 and sleeves 18, 20) are cut and sewn together to form the outer shell 40. The materials for the thermal liner 44 and moisture barrier 42 may also be provided in roll form, and the desired shapes can be stamped out of the rolls of material and formed into the desired shapes and configurations. The upper 72 and lower 76 portions of the moisture barrier 44 or other vented layers may then be joined, such as by overlapping the upper 72 and lower 76 portions and forming the stitch tacks 80 in the desired manner. The stitch tacks 80 may then be sealed with a sealant such as tape 82.
The thermal liner 44 and moisture barrier 42 may then be attached together, or each can be separately located inside the outer shell 40. Various methods of attaching the outer shell 40, thermal liner 44 and moisture barrier 42 together, such as the use of snaps, strips of hook and loop fastening material, stitching, adhesives and the like may be used.
As noted above, each portion 72, 76 of the moisture barrier 42 may be made from separate portions that are coupled together. For example, the torso portion of a typical non-vented moisture barrier 42 may be made from three portions that are coupled together by two stitched “side seams” that extend vertically along the moisture barrier 42 downwardly from the armholes. Thus, each portion 72, 76 of the moisture barrier 42 may include a similar construction and may include similar side seams (see, e.g. side seams 91, 93 of FIGS. 4 and 5). Although the overlapping portions 72, 76 of the moisture barrier 42 may be coupled along their side seams, the resultant connection or side seam may provide an area for moisture infiltration. In particular, a connection along the side seams is a relatively long connection which provides an increased area for moisture to pass, and at least partially closes part of the vent 70. Thus, it may be desirable to couple the portions 72, 76 of the moisture barrier 42 at locations other than the side seams. Of course, the portions 72,76 of the moisture barrier 42 may each be a unitary portion, and would therefore lack any side seams.
While the form of apparatus disclosed herein constitutes a preferred embodiment of the invention, it is to be understood that the present invention is not limited to this precise form of apparatus, and that variations and modifications may be made therein without departing from the scope of the invention.
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