Warriors, first-responders, and industrial workers are examples of personnel who may perform physically-demanding tasks with high rates of metabolic energy expenditures and metabolic heat production. These personnel may be equipped with protective clothing, for example, chemical, biological, radiological, nuclear, and explosive protective clothing, combat clothing, or other individual protective clothing ensembles. Normal mechanisms of dissipating excess metabolic heat, for example, through evaporative cooling in warm and hot environments, may be compromised by the insulation and resistance to water vapor permeation of known protective ensembles. Known protective clothing may increase metabolic heat production due to the metabolic cost of carrying and using the ensemble, and compromise metabolic heat loss by impeding evaporative cooling and dry heat dissipation through conduction, convection, and radiative heat loss. Reducing the thermal burden imposed by protective ensembles has long been, and continues to be, an important need for designers, manufacturers, and users of protective clothing.
Active cooling systems for protective ensembles are known. Active microclimate cooling systems may be thermoelectric systems, or compressor-based systems with a coolant that is circulated in tight-fitting vests, or, perhaps, blower systems that pass filtered outside air over the body and exhaust the air outside the protective suit. Compressor-based or thermoelectric systems may be power hungry, may be expensive, and may be heavy in weight. Air blower systems may be lighter in weight and more comfortable than compressor-based systems, but may be noisy, may have relatively high heat signatures (i.e., may be detected by infrared sensors), may require intake filtering of the air, and may have variable performance, depending on air inlet temperature and humidity. Air blower systems may be impractical in a chemically, biologically, and/or radiologically contaminated environment where filtering a large volume of inlet air may require a large filter capacity.
A long-felt but unsolved need has existed, and continues to exist, for lighter weight, more energy-efficient methods and apparatus to help reduce the thermal load of personnel equipped with protective clothing ensembles.
One aspect of the invention is a protective garment for an animate being. The protective garment may include an impermeable inner layer. A reservoir may be disposed interior to the inner layer, for collecting sweat from the animate being. The garment may include a pump for moving the sweat from the reservoir to a location external to the inner layer. The animate being may be a human.
The sweat collected in the reservoir may be unevaporated liquid sweat, and/or liquid sweat that has exuded or been excreted from the animate being, evaporated, and condensed on the inner layer. The pump may be disposed interior to the inner layer.
The garment may include a distribution system located external to the inner layer, for distributing the sweat on an exterior of the garment. Inlet tubing may have one end in fluid communication with the reservoir and another end connected to an inlet of the pump. Outlet tubing may have one end connected to an outlet of the pump and another end that passes through the inner layer. The outlet tubing may be operatively connected to the distribution system.
The garment may include an external reservoir disposed exterior to the inner layer and fluidly connected to the internal reservoir. The external reservoir may supply water to the internal reservoir for distribution inside or outside of the inner layer.
The distribution system may include wicking material and/or at least one fluid conduit. The distribution system may include at least one fluid conduit in fluid communication with the outlet tubing, and wicking material adjacent to at least one fluid conduit. The wicking material may be an external layer of the garment.
Another aspect of the invention is a method. The method may include providing an animate being with a protective garment and collecting sweat from the animate being in a reservoir. The method may include pumping the sweat to an exterior of the garment. The collected sweat may include sweat that has condensed on an inner layer of the garment. The collected sweat may include unevaporated sweat.
The method may include, after pumping, distributing the sweat on an exterior of the garment. The method may include, after distributing, evaporating the sweat from the exterior of the garment.
Water from a reservoir that is external to the inner layer of the garment may also be collected in the reservoir that collects sweat. One or both of water and sweat may be pumped to the exterior of the garment or distributed between the inner layer and the animate being.
The invention will be better understood, and further objects, features and advantages of the invention will become more apparent from the following description, taken in conjunction with the accompanying drawings.
In the drawings, which are not necessarily to scale, like or corresponding parts are denoted by like or corresponding reference numerals.
A two-stage evaporative cooling process and protective overgarment may reduce overheating and heat illness experienced by those who wear protective garments such as hazardous material suits. The cooling process and overgarment may be suitable for animate beings, in particular, humans. A first stage of evaporative cooling may include evaporation of sweat from the skin of a human, or evaporating sweat from an undergarment that is worn next to the skin. The undergarment may have multiple layers. The sweat vapor may condense on an interior surface of an inner, impermeable layer of the loose-fitting protective garment.
As used herein, “impermeable layer” means a layer of a garment that is at least impermeable to water vapor and water. Preferably, the impermeable layer may also be impermeable to a range of chemical, biological, and other types of hazards. Different chemical, biological, or other types of hazards may require the selection of varying materials for the impermeable layer. Examples of materials for impermeable layers of protective garments are well-known in the field of hazardous materials protection. Such materials may include PTFE (polytetrafluoroethylene, e.g., TEFLON®), Dupont™ Tychem® TK, impermeable Dupont™ Nomex®, Gore® CHEMPACK® Ultra Barrier, or other impermeable materials, such as cotton or nylon fabric coated with polyvinyl chloride (PVC), polyurethane (PU), or rubber.
A second stage of evaporative cooling may occur on the exterior surface of the protective garment, exterior of the impermeable layer. The second stage of evaporative cooling may help dissipate the heat of condensation generated on the interior surface of the impermeable layer. The second stage of evaporative cooling may include pumping condensed sweat from inside the garment to the exterior of the garment and then distributing the condensed sweat on the exterior surface of the garment for re-evaporation. The second stage of evaporative cooling may include pumping unevaporated sweat from inside the garment to the exterior of the garment and then distributing the unevaporated sweat on the exterior surface of the garment for evaporation. In some embodiments, the second stage may include pumping water from inside the garment to the exterior of the garment and then distributing the water on the exterior surface of the garment for re-evaporation.
In the embodiment of
Garment 10 may be an overgarment, that is, the outermost component of a clothing ensemble. As such, garment 10 may be sized to be generally loose-fitting on the wearer of the garment, for example, to allow freedom of movement or to provide ample space for undergarments. Undergarments are not required with garment 10, but may be used. For example, a T-shirt and shorts may be worn under garment 10. For military use, an Army Combat Uniform (ACU) worn with undershirt and underpants may be worn with or without armor under garment 10. Other types of garments may be worn under garment 10. In general, garment 10 may not be pre-tensioned against the wearer, in contrast to elasticized, tight-fitting garments. But, in some embodiments of garment 10, selected pre-tensioning may be used for protective purposes, for example, elastic sleeve cuffs, leg cuffs, neck band, etc.
Garment 10 may include an impermeable, inner layer 32 having an inner surface 34 contiguous with air gap 30. Garment 10 may include a moisture wicking, outer layer 36 disposed opposite impermeable inner layer 32. Garment 10 may have an exterior surface 38. Wicking outer layer 36 may be a wicking fabric, such as polyester, for example. Wicking fabrics may be non-absorbent. Wicking fabrics may include a system of fibers that work like capillaries to carry water. Wicking fabrics may have surface texture, for example, puckers in the fabric may increase the surface area and enhance evaporation. Wicking outer layer 36 may also be a surface treatment, for example, a liquid or spray that may be applied to an outer surface of impermeable inner layer 32. The surface treatment may be a surfactant (e.g., Woolite®) that decreases water surface tension and promotes wetting of fabric.
In some embodiments of the invention, a semi-impermeable layer may be substituted for impermeable layer 32. The semi-impermeable layer may be at least impermeable to liquid water, but semi-impermeable to water vapor, such as a GORE-TEX® type of material.
Human 24 may excrete or exude liquid sweat 40 from skin 26. If no undergarment 28 is present, liquid sweat 40 may evaporate directly from skin 26, pass through air space 30 as sweat vapor, and condense on inner surface 34 as condensed sweat 42. If undergarment 28 is present, liquid sweat 40 may pass through undergarment 28, evaporate from undergarment 28, pass through air space 30 as sweat vapor, and condense on inner surface 34 as re-condensed liquid sweat 42. In either case, skin 26 may be directly or indirectly cooled by evaporation of liquid sweat 40.
As will be described in more detail below, condensed sweat 42 may be collected and transported to wicking outer layer 36. In addition or alternatively, liquid sweat 40 that may not have evaporated may be collected and transported through impermeable inner layer 32 to wicking outer layer 36. On or in wicking outer layer 36, the transported sweat 44 may evaporate from external surface 38 of garment 10. Evaporation of transported sweat 44 from external surface 38 may cool wicking outer layer 36, thereby indirectly cooling impermeable inner layer 32, air space 30, and human 24. It should be noted that, in some embodiments of garment 10, wicking outer layer 36 may be included only in selected areas of garment 10. For example, wicking outer layer 36 may be included on areas of garment 10 that are near to areas of human 24 which exhibit the greatest increases in sweat rate when the core temperature of human 24 increases. Such areas of higher sweat rates in human 24 may be, for example, the head, torso, arms, and upper legs.
The intermittent force of the heel of human 24 on rear insole 54 and reservoir 62 may pump collected sweat from reservoir 62 through an outlet tubing 66 and, ultimately, through impermeable inner layer 32 to wicking outer layer 36. A check valve or one-way valve 64 may be disposed in outlet tubing 66 to prevent backflow into reservoir 62. A quick-disconnect coupling 68 may be included in outlet tubing 66, particularly if boot 14 is a removable type boot.
Movement of elbow joint 72 may cause pump 70 to transport accumulated sweat from reservoir 88 via inlet tubing 76 to outlet tubing 78 and, ultimately, through impermeable inner layer 32 to wicking outer layer 36. Check valves 64 may be disposed in inlet tubing 76 and outlet tubing 78. A quick-disconnect coupling 68 may be included in outlet tubing 78 to facilitate set-up of garment 10 and to provide an option to use or not use pump 70.
Breathing movements of human 24 may cause pump 92 to transport sweat from reservoir 100 through opening 103 and inlet tubing 106 and then to outlet tubing 108 and, ultimately, through impermeable inner layer 32 to wicking outer layer 36. Check valves 64 may be disposed in inlet tubing 106 and outlet tubing 108. A quick-disconnect coupling 68 may be included in outlet tubing 108 to facilitate set-up of garment 10 and to provide an option to use or not use pump 92. In lieu of pump 92, one or more downspouts in the form of tubing 105 (internal to torso portion 104 of garment 10) may carry contents of reservoir 100 to bottom area 58 of boot 14 or to reservoir 62 in boot 14.
As discussed above, pumps 50, 70, and 92 may be powered by the natural movements of human 24 that may occur while performing a task. “Natural body movements” are not movements of human 24 that are consciously and specifically directed to only actuating a pump. One or more of pumps 50, 70, 92 may be used in various combination and numbers. For example, a multiplicity of pumps may be arrayed circumferentially around elbows, knees, waist, shoulder, underarm, hip and other areas such that the action of bending at these locations may result in bladder compression and fluid output, and straightening at these locations may result in bladder re-expansion and fluid intake. Other pumps, such as battery-powered pumps or hand pumps may be used. The sweat may be pumped by the pump or pumps through the outlet tubing and through impermeable inner layer 32 to wicking outer layer 36. From wicking outer layer 36, the sweat may be distributed on external surface 38 of garment 10 and evaporated to thereby cool garment 10.
Outlet tubing from each pump, for example, outlet tubing 66, 78 and 108, may be joined together before piercing impermeable layer 32. Or, each outlet tubing may independently pierce impermeable layer 32.
At opening 112 or openings 112, sweat flowing in the outlet tubing or outlet header may flow into a distribution system for distributing the sweat on or in the outer wicking layer 36.
In
Wicking layer 36 may receive liquid sweat that may exit openings 118 in the network of tubing 116 that forms distribution system 114. Wicking layer 36 may be present wherever impermeable layer 34 is present, or may be selectively used. In
In some embodiments, garment 10 may include one or more external reservoirs 122 (
Thus, one or more of liquid sweat 40 (
Redistribution in space 30 or on undergarment 28 may be accomplished by providing one or more fluid exit ports 130 (
The maximum perspiration rate for a human may be about 1.5 liters per hour. The size and capacity of the reservoirs, pumps, bladders, inlet tubing, outlet tubing, outlet headers, and distribution system tubing may be determined, for example, from the maximum perspiration rate and the number and location of pumps used.
Two-stage evaporative cooling garment 10 may be more efficient under certain temperature conditions. For example, garment 10 may be particularly effective for cooling when the ambient (external to garment 10) wet bulb temperature is less than the temperature of impermeable barrier 32, and the temperature of impermeable barrier 32 is less than the temperature of skin 26 (
Thermal physiological modeling of two-stage evaporative cooling indicates that physiological heat strain may be reduced.
Tests were conducted with a stationary sweating thermal manikin wearing a commercially available chemical protection suit (Blauer Multi-threat Ensemble, Blauer Manufacturing Company, Boston, Mass. 02215). The chemical protection suit was modified for water distribution on its outer surface. The modification included a thin wicking fabric bib and related tubing to distribute water over chest, abdomen and groin areas. The wicking bib system provided an evaporating water surface over about 27% of the suit area. In a climate chamber environment of 95° F. and 40% RH, the wicking bib system increased cooling by 119 watts, compared to cooling without the bib. With 80% of the suit wet, the potential cooling increase is estimated to be about 340 watts. The manikin tests further demonstrate the cooling capability of the two-stage evaporative cooling apparatus and method.
The simulation results of
It will be understood that many additional changes in the details, materials, steps and arrangement of parts, which have been herein described and illustrated in order to explain the nature of the invention, may be made by those skilled in the art within the principle and scope of the invention, as expressed in the appended claims.
The present application is a continuation of and claims the benefit of priority under 35 U.S.C. 120 to U.S. patent application Ser. No. 13/481,292 filed on May 25, 2012, which is a continuation-in-part of and claims the benefit of priority under 35 U.S.C. 120 to International Application Number PCT/US11/30478 filed on Mar. 30, 2011, which claims priority to U.S. provisional patent application Ser. No. 61/319,070 filed on Mar. 30, 2010, all of which are expressly incorporated by reference herein.
The invention described herein may be manufactured, used and licensed by or for the United States Government.
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Parent | 13481292 | May 2012 | US |
Child | 13782132 | US |
Number | Date | Country | |
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Parent | PCT/US2011/030478 | Mar 2011 | US |
Child | 13481292 | US |