The present invention relates to protective garments, and more particularly, to protective garments with a low or reduced friction to increase lubricity.
Protective or hazardous duty garments are used in a variety of industries and settings to protect the wearer from hazardous conditions such as heat, flames, smoke, cold, sharp objects, chemicals, liquids, vapors, fumes and the like. In addition, the wearers of such garments are typically placed under physical strain by carrying heavy gear and equipment. Wearers seek to avoid fatigue to remain mentally sharp and physically able to carry out tasks.
Protective garments are often constructed from sturdy and stiff materials to provide sufficient protection. However, the weight and stiffness of these materials may cause frictional engagement with the wearer or the wearer's clothing.
Accordingly, in one embodiment the present invention is a protective garment with low-friction characteristics, which reduces friction and stress upon the wearer. More particularly, in one embodiment, the invention is a protective garment including an outer shell and an inner liner coupled to the outer shell and positioned such that the inner liner is positioned between a wearer and the outer shell when the garment is worn. The inner liner includes a base material and a high lubricity material which has a higher lubricity than the base material. The high lubricity material is woven into the base material to form a plurality of discrete contact areas in which a plurality of filaments of the high lubricity material are immediately adjacent to each other.
The garment 10 may include various layers through its thickness to provide various heat, moisture and abrasion resistant qualities to the garment 10 so that the garment 10 can be used as a protective, hazardous duty, and/or firefighter garment. For example, the garment 10 may include an outer shell 26, a moisture barrier 28 located inside of and adjacent to the outer shell 26, a thermal liner or barrier 30 located inside of and adjacent to the moisture barrier 28, and an inner liner or face cloth 32 located inside of and adjacent to the thermal liner 30.
The outer shell 26 may be made of or include 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. of Wilmington, Del.), and commercially available polybenzamidazole fibers include PBI fibers (a trademark of PBI Performance Fabrics of Charlotte, N.C.). Thus, the outer shell 26 may be an aramid material, a blend of aramid materials, a polybenzamidazole material, a blend of aramid and polybenzamidazole materials, or other appropriate materials. If desired, the outer shell 26 may be coated with a polymer, such as a durable, water repellent finish (i.e. a perfluorohydrocarbon finish, such as TEFLON® finish sold by E. I. Du Pont de Nemours and Company of Wilmington, Del.). The materials of the outer shell 26 may have a weight of, for example, between about five and about ten oz/yd2.
The moisture barrier 28 and thermal liner 30 may be generally coextensive with the outer shell 26, or spaced slightly inwardly from the outer edges of the outer shell 26 (i.e., spaced slightly inwardly from the outer ends of the sleeves 24, the collar 34 and from the lower edge of the garment 10) to provide moisture and thermal protection throughout the garment 10. The moisture barrier 28 may include a semi-permeable membrane layer 28a and a substrate 28b.
The membrane layer 28a may be generally water vapor permeable but generally impermeable to liquid moisture. The membrane layer 28a may be made of or include expanded polytetrafluoroethylene (“PTFE”) such as GORE-TEX or CROSSTECH materials (both of which are trademarks of W. L. Gore & Associates, Inc. of Newark, Del.), polyurethane-based materials, neoprene-based materials, cross-linked polymers, polyamid, or other materials. The membrane layer 28a may have microscopic openings that permit moisture vapor (such as water vapor) to pass therethrough, but block liquids (such as liquid water, body fluids such as blood and bloodborne pathogens, or chemicals) from passing therethrough. The membrane layer 28a may be made of a microporous material that is either hydrophilic, hydrophobic, or somewhere in between. The membrane layer 28a may also be monolithic and may allow moisture vapor transmission therethrough by molecular diffusion. The membrane layer 28a may also be a combination of microporous and monolithic materials (known as a bicomponent moisture barrier), in which the microporous or monolithic materials are layered or intertwined. The membrane layer 28a may also entirely block vapor, gases, aerosols, etc., and may constitute, for example, neoprene.
The membrane layer 28a may be bonded or adhered to a substrate 28b of a flame and heat resistant material to provide structure and protection to the membrane layer 28a. The substrate 28b may be or include aramid fibers similar to the aramid fibers of the outer shell 26, but may be thinner and lighter in weight. The substrate 28b may be woven, non-woven, spunlace or other materials. In the illustrated embodiment, the membrane layer 28a is located between the outer shell 26 and the substrate 28b. However, the orientation of the moisture barrier 28 may be reversed such that the substrate 28b is located between the outer shell 26 and the membrane layer 28a.
The thermal liner 30 may be made of nearly any suitable material (flame resistant, in one embodiment) that provides sufficient thermal insulation. In one embodiment, the thermal liner 30 may include a relatively thick (i.e. between about 1/16″- 3/16″) batting, felt or needled non-woven bulk or batting material 30a. The batting material 30a 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, foam (either open cell or closed cell), or other suitably thermally insulating materials. The batting 30a may includes one or more layers or a combination of layers of suitable materials. The batting 30a may trap air and possess sufficient loft to provide thermal resistance to the garment 10.
The batting 30a may be quilted to a thermal liner face cloth 30b which can be a weave of a lightweight aramid material. Thus, either the batting 30a alone, or the batting 30a in combination with the thermal liner face cloth 30b, may be considered to constitute the thermal liner 30. In one embodiment, the thermal liner 30 (or the garment 10 as a whole) may have a thermal protection performance (“TPP”) of at least about twenty, and/or the garment 10 as a whole may have a TPP of at least about thirty-five.
In the illustrated embodiment, the thermal liner face cloth 30b is located between the batting 30a and the face cloth 32. However, the orientation of the thermal liner 30 may be reversed such that the batting 30a is located between the thermal liner face cloth 30b and the face cloth 32. Moreover, although the moisture barrier 28 is shown as being located between the outer shell 26 and the thermal liner 30, the positions of the moisture barrier 28 and thermal liner 30 may be reversed such that the thermal liner 30 is located between the outer shell 26 and the moisture barrier 28, or various other orientations or configurations may be used. If desired, the thermal liner 30 may be treated with a water-resistant or water-repellent finish.
The face cloth 32 may be the innermost layer of the garment 10 (best shown in
Each layer of the garment 10, and the garment 10 as a whole, may meet the National Fire Protection Association (“N.F.P.A.”) 1971 standards for protective firefighting garments (“Protective Clothing for Structural Firefighting”), also known as the National Fire Protection Association 1971 Standard on Protective Ensembles for Structural Fire Fighting and Proximity Fire Fighting, which are entirely incorporated by reference herein. The NFPA standards specify various minimum requirements for heat and flame resistance and tear strength. For example, in order to meet the NFPA standards, the outer shell 26, moisture barrier 28, thermal liner 30 and face cloth 32 must be able to resist igniting, burning, melting, dripping, separation, and/or shrinking more than 10% in any direction after being exposed to 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 protective performance rating of at least thirty-five.
As best shown in
The high lubricity material 38 may be woven into, coupled to, or otherwise incorporated into or coupled to the face cloth 32/base material 36. The high lubricity material 38 can be any of a variety of materials, such as a filament yarn or filament materials (including monofilament or multi-filament materials) that are flame/fire resistant and NFPA compliant. For example, the high lubricity material 38 can be a filament form of meta-aramid material (such as NOMEX® material), a para-aramid material (such as KEVLAR® material), aromatic polyimide-amide filaments (such as KERMEL® thermostable organic polymer material), PTFE, polyetheretherketone (PEEK), nylon, fire-resistant viscose, chemically altered spun yarn, or combinations of these materials.
The high lubricity material 38 can be woven into the base material 36 in a variety of manners. For example, in one embodiment the high lubricity material 38 is woven into the base plain weave material 36 using a twill weave pattern for the filament yarns 38. The use of a twill weave pattern helps to ensure that a relatively high percentage of the high lubricity material 38 (i.e. greater than 50%) is facing the desired direction, such as facing the wearer of the garment 10. For example, a 2/1 twill weave pattern, 3/1 twill weave pattern, or the like may be utilized. In addition, various other weaving patterns may be utilized in order to ensure that more of the high lubricity material 38 faces one side of the face cloth 32 than the other side.
As shown in
The high lubricity material 38 may be woven such that the portions of the lines 40 (outside of a contact point 42) constitute about 50%, or less than about 50%, of the cloth 32 in that line 40. However at each contact point 42 high lubricity material 38 may constitute at least about 75%, or substantially 100% or 100% of the face cloth 32. In other words, at each contact point 42 a plurality of filaments of the high lubricity material 38 may be positioned immediately adjacent to each other, with no intervening fibers, and contact an adjacent high lubricity filament 38 to form a generally continuous contact point 42 made of high lubricity material 38. Since a contact point 42 represents the overlap between two lines 40, the density of the high lubricity material 38 at a contact point 42 can be about double the density of the high lubricity material 38 in a line 40.
This concept is conceptualized in
In the embodiment shown in
Any of a variety of patterns of lines 40, which produce the contact points 42, may be utilized. For example, besides the window-pane pattern shown in
In one embodiment, the high lubricity material 38 constitutes less than about 25% by weight of the face cloth 32, or between about 10% and about 50% of the weight of the face cloth 32. The contact points 42 may constitute between about 1 percent and about 50 percent, and more particularly between about 5 percent and about 30 percent (about 15 percent in one embodiment) of the surface area of the face cloth 32. The percent of surface area of the contact points 42 may exceed the percent of weight of the filament/high lubricity material 38 due to the nature of the weave, such as use of a twill or other weave, as noted above, in which more of the high lubricity material 38 faces one side of the face cloth 32. If the contact points 42/high lubricity material 38 constitute too high of a percentage of the surface area, then the cost of the face cloth 32 is increased. On the other hand, if the contact points 42/high lubricity material 38 constitute too low a percentage of the face cloth 32, then insufficient lubricity may be provided.
As noted above, the high lubricity material 38, and in particular the contact points 42, significantly reduce friction between the garment 10 and the wearer. This helps to improve ease of movement and reduces stress on the wearer which allows the wearer to move and react quickly, conserve energy, and extend his or her endurance. Moreover, the garment 10 provides these benefits with relatively minimal usage of the high lubricity material 38. In particular the high lubricity material 38 may be relatively expensive and scarce. Using the arrangement disclosed herein, the face cloth 32 is provided with high lubricity/low friction qualities with relatively little use of high lubricity material 38.
The high lubricity material 38 may be of a higher lubricity than the base material 36 by at least about 50%. The lower the static friction of a material, the higher its lubricity, or “slipperiness.” For example, in one embodiment, due to the high lubricity of the high lubricity material 38, the static friction of the face cloth 32, as a whole, is less than about 0.33 Newtons, or as low as about 0.25 Newtons or less. In contrast, face cloth materials utilizing the same quantity of high lubricity material in a more evenly distributed construction may exhibit static friction values ranging from about 0.33 Newtons to about 0.75 Newtons.
When the high lubricity material 38 is a filament material and the base material 36 is made of spun fibers, over time and launderings the base material 36 tends to shrink relative to the high lubricity material 38 since spun fibers may shrink, but filament material generally does not. This causes the raised nature of the contact points 42 to become even more pronounced, which increases the lubricity of the face cloth 32 as a whole. In addition, the shrinking of the base material 36 allows the face cloth 32 to trap more air between the face cloth 32 and the wearer as the base material 36 is pulled away from an adjacent thermal liner 30 (similar to the cooling effect of a garment made of seersucker material). Accordingly the face cloth 32 may help to increase the thermal insulation qualities of the garment 10.
It should be noted that the material/face cloth 32 described herein can be used in a variety of garments. For example, the particular garment 10 described above for illustrative purposes includes an outer shell 26, a moisture barrier 28 and a thermal liner 30. However, the garment 10 need not necessarily include a moisture barrier 28 and/or thermal liner 30, and/or may include additional layers or features not specifically described herein. Moreover, if the garment 10 does include a moisture barrier 28 and/or thermal liner 30, the moisture barrier 28 and/or thermal liner 30 can differ significantly in materials, characteristics, arrangement and/or design from the moisture barrier 28 and/or thermal liner 30 described herein. For example, if desired the face cloth 32 described herein can be used with nearly any garment, including more general use garments that are not necessarily firefighter or protective garments.
The face cloth 32 may also be used in a variety of garments besides coats. For example the face cloth 32 may be utilized in trousers, vests, hoods, jump suits, socks, gloves, hats, etc. In addition, the face cloth 32 need not necessarily be used as the inner most-layer of the garment. Instead, the face cloth 32 may be utilized as an intermediate layer of a garment to decrease friction between the various layers thereof, as disclosed in, for example, U.S. Pat. Nos. 5,539,928, 5,724,673, and 5,819,316, the entire contents of which are hereby incorporated by reference. For example, the material of the face cloth 32 described herein (or at least the pattern and contact points 42 of the high lubricity material 38) may be used as or on the moisture barrier substrate 28b and/or the thermal liner face cloth 30b described herein, or other layers described herein.
When the face cloth 32 is used as an intermediate layer, it reduces friction between the various layers and thus decreases the amount of work required by the wearer to move and bend the garment 10. The pattern and contact of the high lubricity material 38 may extend entirely through the associated layer, or may exist only in strategic parts thereof (i.e. at the elbows, shoulders, knees, hips, or other joints or areas of high friction).
Although the invention is shown and described with respect to certain embodiments, it should be clear that modifications will occur to those skilled in the art upon reading and understanding the specification, and the present invention includes all such modifications.
This application claims priority to U.S. Provisional Application Ser. No. 61/043,531, filed on Apr. 9, 2008, the entire contents of which are hereby incorporated by reference.
Number | Date | Country | |
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61043531 | Apr 2008 | US |