BACKGROUND OF THE INVENTION

|000 ^' 11 Every winter, drivers are stranded on roads, run the engines of their vehicles until they run out of gas or other vehicle fuel, and then are subjected to hypothermia while they wait For assistance at a location to which they have not brought sufficiently insulating clothing.

Skiers or others participating in winter outdoor activities may similarly -dress for a planned short time outside, but then fall or otherwise, become. -caught by unexpected conditions that lead to exposure to cold sufficient to produce hypothermia. Still others may Find themselves in such conditions with insufficient clothing _, insulation. Hypothermia is a danger to victims of natural disasters, and even to persons simply changing a tire on a roadside in winter night. fOOOlJ Hypothermia is. defined as the unintentional lowering of the deep body (core) temperature below 95.0°F. (35.0°C), Hypothermia can be .mild, moderate, or severe. According to the CDC, 10,649 deaths were attributed to weaiher-related causes in the United States during the period from 2006 through 2010. Two-thirds of these deaths were attributed to. excessive natural cold. (See: Deaths Attributed to Beat, Cold, and Other Weather Events in the United States, 2u06--201Q kf ./Avww

{0003} Since 1 99, the CDC's National Center for Health Statistics (NCHS) has used information from death certificates categorized .with International Classification of Disease codes to. estimate national mortality trends. During 1999, exposure to excessive natural cold (ICD-IO code X31) was listed as the underlying cause of death for 598 persons in the United States, and hypothermia (ICD- I O code T68) was listed as a nature of injury in 1 ,139 deaths. Of the 598 hypothermia-related deaths, 380 (64%) occurred among males, and 359 (60%) of the 59? persons who died of hypotherm ia and whose age was known were aged > 65 years. During 1999, Pennsylvania and New York had the greatest number of hypothermia-related deaths (3 each), and Alaska had the highest death rate (1.9 per 100,000 population), approximately twice that of Montana, which had second-highest rate (0.9).

(0004) Hypotherm ia during cold weather is the result of decreased heat, production, increased heat loss, or impaired thermoregulation. Older persons, wh have a decreased basal metabolic rate, might be at further risk for hypothermia because of impaired physical exertioo, which produces heat to keep the body warm. Inactivity limits heat production through physical exertion, but overexertion can increase evaporation from the respiratory tract and cause fatigue. Shivering also can cause enough lactate generation eventually to produce acidosis and fatigue. Exposure to high winds can further increase heat loss. As body temperature decreases, the hypothalamus fails to compensat body temperature, and the central nervous system follows the progressive systemic depression of metabolism. Finally, metabolic impairment from alcoholism, malnutrition, hypothyroidism, or advanced age can cause poor endurance to cold.. Children, who have a much greater surface-are to metabolic mass, are at even greater risk from ^' hypothermia, _.

10005] Hypothermia-related morbidit i not exclusive to cold northern climates.

Hypothermia can occur in cold and warm climates alike. In fact, a survey of 12 medical centers found that the greatest number of eases of accidental hypothermi occurred in warmer states. Hypother ia has been reported in tropical countries as well. Persons from regions with warmer winters might be at greater risk from the indirect effects of cold weather than persons from regions with colder and longer winters because of inexperience in dealing with cold temperatures. However, geographic distributions might represent not only seasonal temperature variations but also socioeconomic status {which can limi access to controlled indoor

temperature), cultural backgrounds (which can influence beha ior toward individual protection from cold s well as outdoor acti vity), or populations with a higher proportion of elderly persons, § 06| The foregoing indicates that an. emergency a ti-hypothennia system for such, conditions is needed. The present invention provides such a system. It provides a thermally insulating. inflatable vest that is sufficiently portable, to be carried for emergency use in a pocket, purse, backpack, or other such locatio on a person, or also in a compartment of a. vehicle. f0007) The vest provides thermal insulation by being made with air impervious material that also provides for its inflation. The inflating air also provides insulation. Thermal radiation reflecti ve materiai on inwardly facing surfaces of the vest, pref erably inwardly facing surfaees of outer layers of inflated chambers or cells about the vest serves to retain body heat. The multiplicity of individual inflatable chambers about the vest reduces convection heat transfer. The vest thus preferably provides thermal insulation by anti-conduction, anti-radiatio and anti- convection in a highly portable system. 0008} Various other features and attendant advantages of the present invention will become obvious to the reader and become fully appreciated as the same becomes better understood when considered in conjunction with the accompanying drawings, ft is intended that these objects and advantages are within the scope of the present invention. To the

accomplishment of the above and related objects, this invention may be embodied in the form illustrated in the accompanying drawings. Attention being called to the fact, however, that the drawings are illustrative only, and that changes may be made in the specific construction illustrated and described within the scope of this application.

SUMM ARY OF THE INVENTION Θ009{ A highly portable,- inflatable -emergency vest is provided. The vest contains cells, or chambers, which are cross- connected and inflated trough a s mple one-way mouthpiece on the vest's collar, inflating the vest creates a layer of trapped, -still air in much the same way as does goose down, while conforming to the shape of the wearer, thus insulating the wearer's body core while allowing moist air to escape through the arm holes and through the integrated vent holes:. The interior surface of the vest is thermally reflecti ve, thereby keeping body heat trapped next to the user and preventing as much as 80% to 90%. of radiant heat loss. The exterior surface of the vest further is made of radar reflective material. This greatly increases the radar visibilit of the vest, to aid in search and rescue efforts, to locate a wearer who has become lost or incapacitated. This feature is also useful by operators of small boats and kayaks as it. permits positi ve radar indication of the wearer's location on the surface of large bodies of water from long distances. fOO 10J The manufacturing process involves placing a first sheet of material onto second sheet and then bonding the two sheets together along the edges and interiori b either thermally or ultrasonical ly welding the first sheet to the second sheet to form the interconnected chambers. The sheets may be preprinted in any preferred color(s) and with any .sort . of decorative -elements desired, through offset, printing or other known means. Adhesive strips are attached to the vest for closures. Once assembled, the uninilated vest may be stored in small container or pouch for easy portability. For safety high- visibility applications, reflective ink for textiles may be used. Such inks are composed of a water-based (latex} ink base combined with retro-reflecti e rnierolenses. This process is used for direct scree printing onto fabric or plastics, and the end result with respect to visibility is the same. Retro-re f!eetive films may also be used, being applied to the outside sheet before or after the bonding process.

0011 j Other features and advantages of the present invent io are described belo w.

DESCRIPTION OF THE DRAWINGS

[0012] Preferred embodiments will now be described with respect to the following drawings that .illustrate but do not limit the invention.

10013] Figure 1 is a depiction of one embodiment of the vest of the present invention.

100.14] Figure 2 is a depiction of the embodiment of the vest shown in Figure 1 as it is intended to be worn _. , with the vest inflated with air.

£00.15] Figure 3 is a depiction of the vest of the present invention laid out as a flattened single piece.

[00.1:6] Figure 4 is a depiction of the vest of the present inventio laid out as pair o flattened pieces, to be combined into a single vest during the manufacturing process.

[00.17] Figure 5 is a depiction of an embodiment of the present ^' invention in. which the vest further comprises non-inflatable sleeves.

n DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS O lSf The present invention discloses an emergency anti-hypothermia system. In one embodiment, the system, comprises an . ^■ inflatable vest 100. See Figure 1. The vest 100 is made with air impervious material such that air introduced to the interior of the vest 100 is contained therein, thus inflating at least a portion of the vest 100. Preferably, the vest 100 is made from a high tensile-strength polyester film, such as alum mized nylon sheet, coated on one side with polyethylene and metalized on the other). The material is electrically resistant, chemically stabie, Honcombustible (94VTM-2), and comes in thicknesses ranging from 0.00 i inches to 0.014 inches. It is a thermoplastic polymer, and is thermally and oltrasonically fusible. t may come in colors from matte to metaiized.

{0019) The vest 100 is stmctured with a cioseable front 1 10, substantially full sides

122,124 of the vest 100, and a substantial ly full back 130 extending from the neck area 136 to the waist area 138 of the vest 100. The vest 100 moreover has an outer surface and an inner surface, with there being thermal radiation reflective material on at least a portion of the inner surface of the vest 100. When inflated, the vest 1 0 is thermally insulating around the front 1 10, sides 122,124, and back 130.

[0020] In one embodiment the vest 100 is manufactured as a single part. See Figure 3.

In another embodiment the vest 100 is manufactured in two parts, a left side and a right side. See Figure 4. The two part manufacturing method requires the left and right sides to be joined together during final assembly. This can be done by a lateral portion of the material of each of the sides being fused together. Alternatively, these portions can be secured together by tape 202 attached to one of the sides engaging with the other side. An advantage of the two part manufacturing process is that the left and right sides are independently inflatable, so a catastrophic toss of integrity on one side will not cause a loss of insulation on the other side.

|0021| The part of the vest. 1:00 that is inflatable comprises a plurality of interconnected chambers 180, Se Figure 1, The chambers 180 are located on the upper and lower portions of at least the front 1 10 of the vest 100 and cross-connected. Preferably, the chambers 180 are located on the upper and lower portions of the front 1 10, back 130, and side 122, 124 of the vest 100. The inner surface of the vest 100 is on the outside of the chambers 180, and the outer surface of the vest 100 i s on the outside of the chambers 180. Each chamber 180 is form ed by partially fusing portions of the inner surface and the outer surface of the vest 100 to each other, with the fused portions forming an incomplete perimeter of the chamber 18.0. The portio of the perimeter not fused com munieates with an adjoining chamber 180. Thus, each chamber 180 is in communication with at least one other chambe 180, and at least one .chamber 180 is in eomraunication with the inflation, tube. 160. For vests 100 constructed of two sets of

interconnected chambers- 180 (se Figure 4), one inflation tube 1 0 is required for each.

{Θ022 j flie inflation tube(s) 160 comprise a simple one-way mouthpiece, for example a flap valve made of the film material of the vest 100 on the vest's collar 170, See Figure 3. Other configurations of the inflation tube 160 are also contemplated, including a injection molded mouthpiece with an integrated one-way valve. Air introduced into the vest 100 through the inflation tube 160 enters the at least o e chamber 380 communicatin with it, and passes from that chambe 180 into each other chamber 80 via the - communications therebetween until every chamber 180 within the vest. 100 contains air. The inflation tube's 160 one-way valve prevents air from escaping the vest 100 during use. The valve may be manipulated, however, to allow air to escape the vest 100, thereby deflating the vest 100 for subsequent use.

|0023j One or more of the chambers 180 may have an inter-chamber fusion 182 joining the inner surface of the vest 100 to the outer surface of the vest 1 0. See Figure L Such chambers 180 thus appear substantially toroid, rather than spherical. The inter-chamber fusions 182 provide structural rigidity to the vest 100, ^■ allowing it to retain its desired shape when inflated, thus minimizing the loss of heated air between th wearer and the vest 100 through gapping of the vest 100, fO024{ The vest 100 ma be provided in a deflated state, flattened out as a single sheet.

See Figure 3. This allows for compact folding for storage purposes. In one embodiment, in order to use the vest 100, the shoulders 126,128 need to be formed and the front ί 10 needs to be closed. The user thus joins the upper portion 1 14 of one side of the front 1 10 of the vest 100.to the upper portion 134 of the corresponding side of the back 130 of the vest 100 to form one shoulder 126, and joins th upper portion 1 18 of the other side of the front 110 of the vest 100 to the upper porti on 134 of the corresponding side of the back 130. of the vest 100 to form the other shoulder 128. In the preferred embodiments each shoulder 126,128 is formed by a tape 202 attached to the upper portion 1 14 of the front 10 of the vest 100 engaging with the

corresponding upper portion 134 of the back 130 of the vest 100, Alternatively, the tape 202 may be attached to the upper portion 134 of the back 130 of the vest 100, and engages with the eorrespondmg upper portion 1 14 of the fron i 10 of the vest. 100. In either configuration, the tape 202 may further comprise a protective covering on its outside- surface, to prevent adhesion prior to use. In other embodiments the shoulders 126, 128 are pre-tape or fused during the manufacturing process, and no further action need be taken by the user with regard to the shoulders 126,1 8 prio to wearing the vest 100. f 0025j The user dons the vest 100 by inserting each arm through a corresponding armhole formed by the side 122, back 130, front 1 10, and shoulder 126 of the vest 100, The the front 110 of the vest 100 is closed by bringing one side 1 12 of the fron 1 J 0 of the vest 100 into contact with the other side 1 16 of the front 1 10 of the vest 100. See. Figure 2. In the preferred embodiments the first side 1 12 of the front 1 10 of the vest 100 engages with the second side 1 16 of the front 1 10 of the vest 100 by a tape 202, hook and loop fastener (Ve!ero®), or other, adhesive means, which is attached to the first side 1 12 of the front 10 of the vest 100, It does not matter which side (left of right) has the fastening means attached. If used, the tape 202 may further comprise a protective covering on its outside surface, to prevent adhesion prior to use. f0026J In a preferred embodiment, the vest 1 0 comprises a radar reflective materia! on at least a portion of its ou ter surface, This may be aluininized nylon or other high tensi le- strength polyester film metatized on one or ^' both.. surfaces. The radar reflecting properties of materials such as these are well-established. When inflated, this flexible snetaiized material forms three-dimensional radar reflective surfaces, presenting much greater reflective opportunity to incident radar waves, and thus aiding in search and rescue operations. In another preferred embodiment, the vest 100 comprises integrated vent holes 150 located in the front 1 10, sides 122,124, and back 130, These vent holes 150 are punched through the welded vest 100 material at chamber 1 80 intersections points durin the manufacturing process, and allow for greater transfer of moisture from perspiration to the outside of the garment, thereby enhancing wearer comfort and the vest's TOO insulating properties, in yet another preferred embodiment, the vest 100 comprises an integrated inflation tube 160, This tube 160, positioned on the front collar 1 70, greatly improves the process of vest 100 inflation. In yet another preferred embodiment, the vest 100 comprises a non-inflating integrated collar 170. This collar 1 70 is produced by fusing both layers of the vest 100 material, thus creating a wind barrier and additional heat reflective surface at the back of the wearer 's neck, aiding in overall comfort and utility. In the most preferred embodiment each of these features is incorporated into the vest 100.

|Θ0. 7) In one variant, the vest 100 has a pair of non- inflatable sleeves 190. See Figure 5.

The sleeves 190 are constructed of a single ply of inwardly alumini ed material , with vent holes 150 and tape 202 wrist closures.- This configuration provides additional insulation to the

extremities, while allowing the overall bulk of the vest 100 to remain as small as possible.

{ 0028| ^' W hat has been descr ibed and illustrated herein is a preferred embodiment of the invention along with some it its variations. The terms, descriptions and figures used herein are set forth by way of illustration only and are not meant as l imitations. Those skilled in the art will recognize that many variations are possible within the spirit and scope of the invention in which all terms are meant in their broadest, reasonable sense unless otherwise indicated. Any headings utilized within the descriptio are for convenience only and have no legal or limiting effect.