ADVANCED ENGINEERED GARMENT

Information

  • Patent Application
  • 20100325773
  • Publication Number
    20100325773
  • Date Filed
    June 24, 2009
    15 years ago
  • Date Published
    December 30, 2010
    14 years ago
Abstract
An under body armor hybrid fabric garment has first and second fabric portions. The first fabric portion, configured to cover an upper torso region of a user's body left exposed by the body armor and extending into a second body transition region covered by the body armor, is formed of low or no stretch fabric. The second fabric element, configured to cover a lower torso region of the user's body underneath the body armor, is formed of stretchable fabric.
Description
TECHNICAL FIELD

This disclosure relates to garments, and, particularly, to garments worn by an individual underneath body armor.


BACKGROUND

Body armor is well known for use by persons in combat and battlefield or analogous situations for preventing ballistic projectiles from penetrating covered regions of the body of the wearer. More recently, body armor covering increased surface area of the body has been developed. For example, U.S. Pat. No. 5,060,314 to Lewis describes a ballistic resistant jacket that extends up to 3 inches below the wearer's waist, with a back panel, a combined front and left side panel, a combined front and right side panel, a collar and over-the-shoulder portions. U.S. Pat. No. 6,363,527 to Biermann et al. describes a body armor vest formed of thermally conductive fibers, for improved heat transfer, and moisture-wicking materials, to keep moisture away from the body and the body armor. U.S. Pat. No. 6,892,392 to Crye et al. describes a body armor vest having foam pads affixed to an interior of the vest defining multiple vertically extending air channels between the wearer and the vest, wherein the air channels promote ventilation and cooling of the wearer.


SUMMARY

The present disclosure is directed, in part, to garments, such as battlefield and analogous garments, worn under body armor to provide a durable, low stretch or no stretch outer layer covering regions of a user's body left exposed by the body armor with a ventilated, stretchable inner layer covering regions of the wearer's body covered by the body armor.


According to one aspect, an under body armor hybrid fabric garment comprises a first fabric portion and a second fabric portion. The first fabric portion comprises low stretch or no stretch fabric configured to cover an upper torso region of a user's body, wherein the first fabric portion covers a first body region left exposed by the body armor and extends into a second body transition region covered by the body armor. The second fabric portion comprises stretchable fabric configured to cover a lower torso region of the user's body underneath the body armor.


Implementations of this aspect may include one or more of the following additional features. The first fabric portion may be formed from low stretch woven fabric. The woven fabric can include a double weave construction (e.g., for increased insulation and/or decreased air permeability, such as for colder weather applications). The low stretch woven fabric is selected from the group of materials consisting of: synthetic yarns and/or fibers (e.g., polyester, nylon, etc.), natural yarns and/or fibers (e.g., cotton and/or wool), and specialty yarns and/or fibers (e.g., flame retardant yarns and/or fibers, including m-aramid (such as those sold by E.I. duPont under the trademark NOMEX®), melamine, flame retardant cotton, flame retardant nylon, a flame retardant treated cotton/nylon blend, modacrylic, and combinations thereof). The first fabric portion may be comprised of yarns and/or fibers resistant to melting and dripping when exposed to a flame or high temperatures. The first fabric portion has predetermined air permeability, e.g., the first fabric portion has predetermined air permeability in the range of between about 0 CFM to about 200 CFM, preferably between about 5 CFM to about 100 CFM, more preferably, between about 20 CFM and about 40 CFM. The second fabric portion may be formed from synthetic yarns and/or fibers (e.g., nylon, polyester, polypropylene, and combinations thereof), natural yarns and/or fibers, and/or combinations thereof. The second fabric portion may be comprised of flame retardant yarns and/or fibers (e.g., m-aramid, flame retardant treated cotton, acrylic, and combinations thereof). In some cases, the second fabric portion includes yarns and/or fibers resistant to melting and dripping when exposed to fire or high heat (e.g., cotton, wool, acrylic, and combinations thereof). The second fabric portion may be comprised of a fabric with one-way or two-way stretch. The second fabric portion has plated jersey, double knit, single jersey knit, single face terry loop in plated construction, or single face terry loop in non-plated construction. In some cases, the plated jersey construction can include a combination of nylon yarns and cotton yarns, wherein the nylon yarns are shown predominantly on the technical face of the fabric and the cotton yarns are shown predominantly on the technical back of the fabric. Alternatively, the plated jersey construction can include a combination of m-aramid yarns (e.g., NOMEX® yarns) and cotton yarns, wherein the m-aramid yarns are shown predominantly on the technical face of the fabric and the cotton yarns are shown predominantly on the technical back of the fabric. The second fabric portion has a plated jersey construction including a combination of a first set of m-aramid yarns and a second set of m-aramid yarns, wherein the first set of m-aramid yarns are shown predominantly on the technical face of the fabric and the second set of m-aramid yarns are shown predominantly on the technical back of the fabric. The second fabric portion has a plated jersey construction including a combination of m-aramid yarns and wool yarns, wherein the m-aramid yarns are shown predominantly on the technical face of the fabric and the wool yarns are shown predominantly on the technical back of the fabric. The second fabric portion has a plated jersey construction including a combination of nylon yarns and wool yarns, wherein the nylon yarns are shown predominantly on the technical face of the fabric and the wool yarns are shown predominantly on the technical back of the fabric. Preferably, the second fabric portion is comprised of wicking fabric, e.g. POWER DRY® textile fabric, as manufactured by Malden Mills Industries, Inc. of Lawrence, Mass. Spandex yarn can be included in the second fabric portions to form a fitted garment with enhanced resistance to folding, creases and bulging. The second fabric portion has denier gradient, i.e. relatively finer dpf on an outer surface of the fabric and relatively more coarse dpf on an inner surface of the fabric, for encouraging flow of liquid sweat from the inner surface of the second fabric portion to the outer surface of the second fabric portion (i.e., for better water management). The second fabric portion has predetermined air permeability, e.g., the second fabric portion may have predetermined air permeability greater than about 100 CFM. The second fabric portion has single face plated construction. Preferably, the single face plated construction includes a sinker loop surface, which defines the inner surface of the second fabric portion. The sinker loop surface can have raised sinker loop finish, velour (napped) finish, cut loop velour finish, or un-napped loop form. The sinker loop surface defines a plurality of discrete inner regions of loop yarn including one or more first discrete inner regions having first inner pile height, and defines one or more other discrete inner regions having contrasting inner pile height relatively greater than the first inner pile height, wherein the one or more first discrete inner regions of loop yarn, together with the one or more other discrete inner regions, define air channels between the user's skin and an opposed inner base surface of the fabric, thereby to facilitate ventilation and to reduce the number of contact points with the user's skin. The air channels comprise a plurality of vertical channels, horizontal channels, diagonal channels, or combinations thereof. The air channels may include a plurality of intersecting channels. The plurality of discrete inner regions of loop yarn are disposed in a pattern corresponding to one or more predetermined regions of the user's body. The plurality of discrete inner regions of loop yarns may be disposed on a front surface of the second fabric portion, on a back surface of the second fabric portion, or on both a front and a back surface of the second fabric portion. In some cases, the second fabric portion includes a double face fabric. The double face fabric can include a first surface defining an inner surface of the second fabric portion, the inner surface defining a plurality of discrete inner regions of loop yarn including one or more first discrete inner regions having first inner pile height, and defining one or more other discrete inner regions having contrasting inner pile height relatively greater than the first inner pile height, wherein the one or more first discrete inner regions of loop yarn, together with the one or more other discrete inner regions, define inner air channels between the user's skin and an opposed inner base surface of the fabric, thereby to facilitate ventilation and to reduce the number of contact points with the user's skin. The double face fabric still further comprises a second surface defining an outer surface of the second fabric portion, the outer surface defining a plurality of discrete outer regions of loop yarn, the discrete outer regions of loop yarn including one or more first discrete outer regions having first outer pile height, and one or more other discrete outer regions having contrasting outer pile height relatively greater than the first outer pile height, wherein the discrete outer regions of loop yarn, together with the one or more other discrete outer regions, define outer air channels between an inner surface of the body armor and an opposed outer base surface of the fabric, thereby to facilitate ventilation and to reduce the number of contact points with the inner surface of the body armor. The inner and/or outer air channels may comprise a plurality of vertical channels, horizontal channels, diagonal channels, or combinations thereof. The inner and/or out air channels may include a plurality of intersecting channels. The plurality of discrete inner regions of loop yarn may be disposed in a pattern corresponding to one or more predetermined regions of the user's body. The plurality of discrete inner and outer regions of loop yarn may be disposed on a front surface of the second fabric portion, a back surface of the second fabric portion, or both.


In another aspect, a battlefield garment system comprises a body armor element and an under-armor garment. The under-armor garment comprises a first textile fabric portion including low stretch fabric configured to cover an upper torso region of a user's body, the first textile fabric portion covering a first body region left exposed by the body armor element and extending into a second body transition region covered by the body armor element. The under-armor garment further comprises a second textile fabric portion comprising stretchable fabric configured to cover a lower torso region of the user's body underneath the body armor element.


Preferred implementations of this aspect may include one or more of the following additional features. The first textile fabric portion is configured to cover the user's shoulder regions and extends below the elbows down towards the user's wrists defining a pair of fabric arms. At least one of the fabric arms includes a pocket configured to carry ammunition. The first textile fabric portion has woven construction. The first textile fabric portion is treated with durable water repellent (DWR), camouflage and/or infrared radiation reduction. The second textile fabric portion comprises fibers of stretch and/or elastic material incorporated in the fabric. The second textile fabric portion includes a raised inner surface. The raised inner surface may be finished as raised sinker loop surface, velour surface, cut loop velour surface, or un-napped loop form. The raised inner surface defines one or more discrete inner regions of loop yarn including one or more first discrete inner regions having first inner pile height, and one or more other discrete inner regions having contrasting inner pile height relatively greater than the first inner pile height, wherein the one or more first discrete inner regions, together with the one or more other discrete inner regions, defines inner air channels between the user's skin and an opposed inner base surface of the fabric, thereby to facilitate ventilation, and to reduce the number of contact points with the user's skin. The first inner pile height is low pile, no pile or a combination thereof. The contrasting inner pile height is high pile, low pile, or combinations thereof. Preferably, the first discrete inner regions having first inner pile height comprise loop yarn formed to low pile height of between about 1.0 mm to about 3.0 mm. The other discrete inner regions comprise loop yarn formed to pile height in the range of greater than about 2.0 mm up to about 6.0 mm. The inner air channels comprise a plurality of vertical channels, horizontal channels, diagonal channels, or combinations thereof. The plurality of discrete inner regions of loop yarn correspond to one or more predetermined regions of the user's body selected from the group consisting of: spinal cord area, spine, back area, upper back area, lower back area, front chest area, breast area, and abdominal area. The discrete inner regions of loop yarn can be disposed on a front surface of the second textile fabric portion, on a back surface of the textile fabric portion, or on both a front surface and a back surface of the textile fabric portion. The second fabric portion may also include a raised outer surface. Preferably, the raised outer surface defines one or more discrete outer regions of loop yarn, the discrete outer regions of loop yarn including one or more first discrete outer regions having first outer pile height, and one or more other discrete outer regions having contrasting outer pile height relatively greater than the first outer pile height, wherein the one or more first discrete outer regions, together with the other discrete outer regions, define outer air channels between an inner surface of the body armor element and an opposed outer base surface of the fabric, thereby to facilitate ventilation and reduce the number of contact points with the inner surface of the body armor element. The first outer pile height may be low pile, no pile or a combination thereof, and preferably a pile height of about 1.0 mm to about 3.0 mm. The contrasting outer pile height may be high pile, low pile or a combination thereof, and preferably in the range of greater than about 2.0 mm up to about 6.0 mm. The outer air channels may comprise a plurality of horizontal and vertical channels. The plurality of inner and outer regions of loop yarn may be disposed on a front surface of the second textile fabric portion, a back surface of the second textile fabric portion, or on a front surface and a back surface of the second textile fabric portion.


In yet another aspect, a method of forming an under body armor hybrid fabric battlefield garment comprises the steps of: forming a first fabric portion corresponding to an upper torso region of a user's body from low stretch or no stretch fabric, wherein the first fabric portion covers a first body region left exposed by the body armor and extends into a second body transition region covered by the body armor; forming a second fabric portion corresponding to a lower torso region of the user's body from stretchable fabric, wherein the second fabric portion is configured to cover a lower torso region of the user's body underneath the body armor, and joining together the first and second fabric portions to form the hybrid fabric battlefield garment.


Preferred implementations of the method may include one or more of the following additional features. The step of forming the second fabric portion comprises combining yarns and/or fibers selected from the group consisting of: synthetic yarns and/or fibers, natural yarns and/or fibers, and combinations thereof to form a knit fabric. The step of forming the second fabric portion comprises combining yarns and/or fibers to form plated jersey fabric, double knit fabric, or single jersey knit fabric. The step of forming the second fabric portion comprises combining yarn and/or fibers to form single face plated fabric with plated sinker loop. Preferably, forming the single face fabric comprises finishing a first surface of the single face plated fabric to form one or more discrete inner regions of loop yarn, including, forming one or more first discrete inner regions having first inner pile height, and forming one or more other discrete inner regions having contrasting inner pile height relatively greater than the first inner pile height, wherein the one or more first discrete inner regions, together with the one or more other discrete inner regions, define inner air channels between the user's skin and an opposed inner base surface of the fabric, thereby to facilitate ventilation and to reduce the number of contact points with the user's skin. The first surface of the single face plated fabric may define an inner surface of the second fabric garment. The one or more discrete inner regions of loop yarn may be formed in a pattern corresponding to one or more predetermined regions of the user's body. The discrete inner regions of loop yarn may be disposed on a front surface of the second textile fabric portion, or on a back surface of the second fabric portion, or on a front surface and a back surface of the second fabric portion. The step of forming the second fabric portion comprises combining yarns and/or fibers to form double face fabric. In some cases, forming the double face fabric comprises finishing an inner surface of the double face fabric to form one or more discrete inner regions of loop yarn forming one or more first discrete inner regions having first inner pile height, and forming one or more other discrete inner regions having contrasting inner pile height relatively greater than the first inner pile height, wherein the one or more first discrete inner regions, together with the one or more other discrete inner regions, define inner air channels between the user's skin and an opposed inner base surface of the fabric, thereby to facilitate ventilation and to reduce the number of contact points with the user's skin. Forming the double face fabric further comprises finishing an outer surface of the double face fabric to form one or more discrete outer regions of loop yarn, forming one or more first discrete outer regions having first outer pile height, and one or more other discrete outer regions having contrasting outer pile height relatively greater than the first outer pile height, wherein the one or more first discrete outer regions, together with the other discrete outer regions, define outer air channels between an inner surface of the body armor and an opposed outer base surface of the fabric, thereby to facilitate ventilation and to reduce the number of contact points with the inner surface of the body armor. The inner surface of the double face fabric may define an inner surface of the second fabric garment, and the outer surface of the double face fabric defines an outer surface of the second fabric garment. The discrete inner and outer regions of loop yarn may be disposed on a front surface of the second fabric portion, or on a back surface of the second fabric portion, or on both a front and a back surface of the second fabric portion.


An under-the-armor battlefield garment is many times employed as the only garment layer, which requires it to serve the wearer as an outer layer, where left exposed by the body armor, as well as an inner layer underneath regions covered by the body armor. Therefore, there is need for an under-the-armor battlefield garment equipped to serve multiple requirements such as providing a tough, durable, low stretch or no stretch outer layer, and a comfortable, stretchable inner layer that provides adequate ventilation.


The details of one or more embodiments of the invention are set forth in the accompanying drawings and the description below. Other features, objects, and advantages of the invention will be apparent from the description and drawings, and from the claims.





DESCRIPTION OF DRAWINGS


FIG. 1 is a front perspective view of a battlefield garment and body armor system.



FIG. 1A is a rear perspective view of a battlefield garment and body armor system.



FIG. 1B is cross-sectional view of a second fabric portion of a battlefield garment having a plated jersey or double knit construction.



FIG. 1C is a cross-sectional view of a second fabric portion of a battlefield garment having a single jersey construction.



FIG. 1D is a cross-sectional view of a second fabric portion of a battlefield garment having a single face construction with air channels.



FIG. 2A is a front perspective view of a battlefield garment to be worn under body armor showing a plurality of discrete regions of loop yarn on an inner front surface of the garment, including a plurality of first discrete inner regions having a first pile height, and a plurality of other discrete inner regions having contrasting pile height relatively greater than the first pile height.



FIG. 2B is a front perspective view of a battlefield garment to be worn under body armor showing a plurality of discrete regions of loop yarn on an outer front surface of the garment, including a plurality of first discrete outer regions having a first pile height, and a plurality of other discrete outer regions having contrasting pile height relatively greater than the first pile height.



FIG. 3 is a front perspective view of the battlefield garment, illustrating the flow of ventilating air through channels formed between a user's skin and an opposed inner base surface of the fabric by a plurality of discrete regions of loop yarn on an inner front surface of the garment.



FIG. 4 is a front perspective view of a battlefield garment and body armor system illustrating the flow of ventilating air through channels formed between an inner surface of the body armor and an opposed outer base surface of the fabric by a plurality of discrete regions of loop yarn on an outer front surface of the garment.



FIG. 5A is a rear perspective view of a battlefield garment to be worn under body armor showing a plurality of discrete regions of loop yarn on an inner back surface of the garment, including a plurality of first discrete inner regions having a first pile height, and a plurality of other discrete inner regions having contrasting pile height relatively greater than the first pile height.



FIG. 5B is a rear perspective view of a battlefield garment to be worn under body armor showing a plurality of discrete regions of loop yarn on an outer back surface of the garment, including a plurality of first discrete outer regions having a first pile height, and a plurality of other discrete outer regions having contrasting pile height relatively greater than the first pile height.



FIG. 6 is a rear perspective view of the battlefield garment illustrating the flow of ventilating air through channels formed between a user's skin and an opposed inner base surface of the fabric by a plurality of discrete regions of loop yarn on an inner back surface of the garment.



FIG. 7 is a rear perspective view of a battlefield garment and body armor system illustrating the flow of ventilating air through channels formed between an inner surface of the body armor and an opposed outer base surface of the fabric by a plurality of discrete regions of loop yarn on an outer back surface of the garment.





DETAILED DESCRIPTION

Referring to FIGS. 1, 1A, 2A, 2B, 5A and 5B, a battlefield garment 10 has a first fabric portion 12 and a second fabric portion 14. Each fabric portion consists of a single layer fabric. The first and second fabric portions 12, 14, respectively, can be formed, for example, from two or more distinctive materials, each modifiable to meet different ambient conditions and/or different physical activities. The first fabric portion 12 is formed from a low or no stretch fabric and configured to cover an upper torso region of a user's body including a first body region 12′ left exposed by body armor 16, extending into a second body transition region 12″ covered by the body armor. As illustrated in FIGS. 2A and 5A, the first fabric portion 12 covers the user's shoulder regions and extends below the elbows down towards the user's wrists, and includes pockets 18 sewn into the arms, which allows the user/soldier to carry, e.g., extra ammunition and other utilities. The low or no stretch fabric is, preferably, a low stretch woven material or another non-stretchable material. A battlefield garment 10 formed of non-stretchable or low stretch material, e.g., like woven fabric in the upper portion 12 of the garment enables a soldier to carry more ammunition or other materials, placed in the pockets sewn on the woven sleeve, without stretching the fabric or distorting the fit of the garment. If the upper portion 12 of the garment were, instead, formed of knit or excessively stretchable woven fabric, heavy ammunition loaded into the pockets 18, would distort the garment fit, generate creases and folds, and cause chaffing with the edges or neck area of the body armor. In addition to being low or no stretch, the exposed region 12′ of the first fabric portion 12 is required to be tough and durable, and may be treated with durable water repellent, camouflage, and/or infrared radiation reduction. Preferably, the first fabric portion 12 is formed of materials with flame retarding properties (e.g., m-aramid (such as NOMEX®), PBI®, melamine, flame retardant cotton, flame retardant nylon, a flame retardant treated cotton/nylon blend, and combinations thereof) or no-melt, no-drip properties upon exposure to fire.


Referring still to FIGS. 1, 1A, 2A, 2B, 5A and 5B, the second fabric portion 14 covers a lower torso region of the user's body and is designed to fit underneath the body armor 16. The second fabric portion 14 is formed of stretchable fabric and configured to cover a lower torso region of the user's body beneath the body armor 16. The stretchable fabric is preferably of knit construction, and more preferably of plated knit construction, with good wicking, good water management, and good breathability. In addition, forming the lower torso region of a slightly fitted fabric minimizes folding, creases and bulging, thereby to minimize chafing of the wearer's skin. The plated knit construction can be made with different yarn combinations, which can be adjusted, for example, according to the intended use. For example, for warm weather applications the plated knit construction can include a combination of nylon (or flame retardant) yarns and cotton yarns wherein the nylon (or flame retardant) yarns are arranged such that they appear predominantly on the technical face of the fabric and the cotton yarns are arranged such that they appear predominantly on the technical back of the fabric. For colder weather applications, for example, the plated knit construction can include a combination of nylon (or flame retardant) yarns and wool yarns wherein the nylon (or flame retardant) yarns are arranged such that they appear predominantly on the technical face of the fabric and the wool yarns are shown predominantly on the technical back of the fabric. The wool yarn can provide increased thermal insulation, as compared to cotton yarns, without detracting from tangential air flow in the area between the user's skin and opposed inner base surface of the fabric, thereby to minimize heat build-up under the body armor. The terms “technical face” and “technical back” generally refer to sides of the fabric as it exits the knitting machine. As used herein, the term technical face also refers to an outer surface of the second fabric portion.


As illustrated in FIG. 1B, the second fabric portion 14 may have plated jersey or double knit construction. In this embodiment, second fabric portion 14 has a smooth inner surface 13 (the surface in contact with the user's skin) and a smooth outer surface 15 (the surface exposed to the body armor). Suitable materials include POWER DRY® textile fabric, as manufactured by Malden Mills Industries, Inc.



FIG. 1C illustrates an alternative embodiment wherein the second fabric portion 14 has single face plated construction, e.g. as in the POWER STRETCH® textile fabric, also as manufactured by Malden Mills Industries, Inc. According to this embodiment, a first surface 17 of the second fabric portion 14 is finished (e.g., in loop form 19, or velour (napped finish, or cut-loop velour 19′) and defines an inner surface of the second fabric portion 14. The finished surface 19, 19′ contacts the user's skin providing enhanced comfort, water management, and enhanced air movement and ventilation. The smooth outer surface 15 is exposed to the body armor. Alternatively, as illustrated in FIG. 1D, the first surface 17 may be finished in a pattern of contrasting pile heights, thereby forming channels 21 for enhanced air movement and ventilation. In an alternative embodiment, the pattern of contrasting pile heights may be arranged to correspond with one or more predetermined regions of the user's body, as shown in FIGS. 2A, 3, 5A and 6.


In addition, second fabric portion 14 may be finished, as described above, on both inner and outer surfaces for enhanced thermal insulation. For example, FIGS. 2A-7 illustrate a plurality of discrete regions of loop yarn 22, 24, 32, 34 disposed on inner and outer, and front and back, surfaces of the second fabric portion. The discrete regions of contrasting pile height upon the inner and outer, and front and back, surfaces of the second fabric portion 14 increase the comfort level and enhance air movement to reduce heat stress under the body armor 16. For example, as illustrated in FIGS. 2A and 5A, a plurality of discrete inner regions of loop yarn 20 are disposed upon an inner surface of the second fabric portion, between the user's skin and opposed inner base surface of the fabric, corresponding to predetermined regions of the user's body, including, for example, the spinal cord area, spine, back area, upper back area, lower back area, front chest area, breast area and abdominal area. The discrete inner regions of loop yarn 20 include a plurality of first discrete inner regions 22 having first pile height, and a plurality of other discrete inner regions 24 having contrasting pile height relatively greater than that of the first discrete inner regions 22. For example, the first pile height may be low pile, no pile or combinations thereof. Preferably, the low pile height is between about 1.0 mm and about 3.0 mm. The contrasting pile height may be high pile, low pile or combinations thereof, preferably, greater than about 2.0 mm up to about 6.0 mm.


Referring to FIGS. 3 and 6, the first discrete inner regions 22, together with the other discrete inner regions 24, define air channels between the user's skin and the opposed inner base surface of the fabric, thereby facilitating ventilation, illustrated by arrows 26, and reducing the number of contact points with the user's skin.


Additionally, FIGS. 2B and 5B illustrate an outer surface of the second fabric portion, with a plurality of discrete outer regions of loop yarn 30 disposed thereon and configured to fit between an inner surface the body armor and the opposed outer base surface of the fabric. The discrete outer regions of loop yarn 30 include a plurality of first discrete outer regions 32, having a first pile height, and a plurality of other discrete outer regions 34 having contrasting pile height relatively greater than that of the first discrete outer regions 32. For example, the first pile height may be low pile, no pile or combinations thereof. Preferably, the low pile height is between about 1.0 mm and about 3.0 mm. The contrasting pile height may be high pile, low pile, or combinations thereof, preferably, greater than about 2.0 mm up to about 6.0 mm. Referring to FIGS. 4 and 7, the first discrete outer regions 32, together with the other discrete outer regions 34, define air channels between the inner surface the body armor 16 and the opposed outer base surface of the fabric, thereby facilitating ventilation, illustrated by arrows 36, and reducing the number of contact points with the inner surface of the body armor.


A number of embodiments have been described. Nevertheless, it will be understood that various modifications may be made without departing from the spirit and scope of the disclosure. For example, the second fabric element may be produced by any procedure suitable for combining yarns and/or fibers to create regions with contrasting pile heights and/or regions of no pile. For improved stretch, the second fabric portions may have fibers of stretch and/or elastic material incorporated into the stitch yarn. The first and second fabric portions may have predetermined air permeability. For example, the first fabric portion may have predetermined air permeability of about 0 CFM to about 200 CFM, and the second fabric portion may have predetermined air permeability greater than about 100 CFM. Accordingly, other embodiments are within the scope of the following claims.

Claims
  • 1-95. (canceled)
  • 96. An under body armor hybrid fabric garment, comprising: a first fabric portion comprising low stretch or no stretch fabric configured to cover an upper torso region of a user's body, the first fabric portion covering a first body region left exposed by the body armor and extending into a second body transition region covered by the body armor; anda second fabric portion comprising stretchable fabric configured to cover a lower torso region of the user's body underneath the body armor, wherein the second textile fabric portion has an inner surface including at least one region of pile or raised fibers.
  • 97. The hybrid fabric garment of claim 96, wherein the first fabric portion comprises low stretch woven fabric.
  • 98. The hybrid fabric garment of claim 97, wherein the woven fabric comprises a double weave construction.
  • 99. The hybrid fabric garment of claim 97, wherein the second fabric portion comprises knit fabric.
  • 100. The hybrid fabric garment of claim 96, wherein the inner surface has a finish selected from the group consisting of: raised sinker loop surface, velour surface, stand alone loop un-napped, and cut loop velour surface.
  • 101. The hybrid fabric garment of claim 96, wherein the second fabric portion has a outer surface including at least one region of pile or raised fibers.
  • 102. The hybrid fabric garment of claim 96, wherein the second fabric portion comprises moisture wicking fabric.
  • 103. The hybrid fabric garment of claim 102, wherein the moisture wicking fabric comprises: an outer surface defining an outer surface of the second fabric portion and formed of yarn and/or fibers of relatively fine denier per filament; and an inner surface defining the inner surface of the second fabric portion and formed of yarn and/or fibers of relatively coarse denier per filament, for encouraging flow of liquid sweat from the inner surface of the second fabric portion toward the outer surface of the second fabric portion.
  • 104. The hybrid fabric garment of claim 96, wherein the first fabric portion has a first predetermined air permeability, and wherein the second fabric portion has a second predetermined air permeability substantially greater than the first predetermined air permeability.
  • 105. The hybrid fabric garment of claim 104, wherein the first predetermined air permeability is less than 40 CFM, and wherein the second predetermined air permeability is greater than 100 CFM.
  • 106. The hybrid fabric garment of claim 96, wherein the second fabric portion comprises fabric with one-way stretch.
  • 107. The hybrid fabric garment of claim 96, wherein the second fabric portion comprises fabric with two-way stretch.
  • 108. The hybrid fabric garment of claim 96, wherein the second fabric portion comprises spandex in a form fitted fabric for enhanced resistance to folding, creasing and bulging.
  • 109. An under body armor hybrid fabric garment, comprising: a first fabric portion comprising low stretch or no stretch fabric configured to cover an upper torso region of a user's body, the first fabric portion covering a first body region left exposed by the body minor and extending into a second body transition region covered by the body armor; anda second fabric portion comprising stretchable fabric configured to cover a lower torso region of the user's body underneath the body armor,wherein the first fabric portion has a first predetermined air permeability, andwherein the second fabric portion has a second predetermined air permeability substantially greater than the first predetermined air permeability.
  • 110. The hybrid fabric garment of claim 109, wherein the first fabric portion comprises low stretch woven fabric.
  • 111. The hybrid fabric garment of claim 110, wherein the woven fabric comprises a double weave construction.
  • 112. The hybrid fabric garment of claim 110, wherein the second fabric portion has a knit construction selected from the group consisting of plated jersey, double knit, single jersey, single face terry loop in plated construction, and single face terry loop fabric in non-plated construction.
  • 113. The hybrid fabric garment of claim 112, wherein the first predetermined air permeability is less than 40 CFM, and wherein the second predetermined air permeability is greater than 100 CFM.
  • 114. The hybrid fabric garment of claim 112, wherein the first predetermined air permeability is in the range of about 0 CFM to about 200 CFM, and wherein the second predetermined air permeability is greater than 100 CFM.
  • 115. The hybrid fabric garment of claim 109, wherein the second textile fabric portion further comprises fibers of stretch and/or elastic material.