Abstract: A method of forming a pressure vessel including adsorbent materials comprises forming a continuous liner defining a central bore, aligning a screw within the central bore; and distributing adsorbent materials within the central bore using the screw. A method of forming adsorbent materials for installation in a continuous pressure vessel comprises encasing a support structure within a permeable liner and distributing adsorbent materials between the support structure and the permeable liner. A method of forming an adsorbent framework for installation in a continuous pressure vessel comprises distributing adsorbent materials between corrugated sheets, coupling respective ends of the corrugated sheets to form an adsorbent layer, and rolling the adsorbent layer to form an adsorbent framework shaped for installation into the continuous pressure vessel.

Abstract: An oxygen belt breathing pack includes at least one flexible polymeric pressure vessel connected with sections of flexible conduit to either a sealing fitting, an inlet fitting, another section of flexible conduit attached to another pressure vessel or a manifold. The manifold provides connections for a high pressure regulator and oxygen fill source. The pressure vessel and sections of flexible conduit are encased in high strength fiber material. The pressure vessel is wrapped in high strength ballistic ribbon material. The high pressure regulator is connected to a low pressure hose connected to a nasal cannula. A flexible container is formed of resilient material, and is sized and shaped to accommodate the at least one pressure vessel, the sections of flexible conduit, the manifold and to provide storage for the nasal cannula. The container is formed as a belt or lightweight backpack. A pressure gauge monitors oxygen use by the patient.

Abstract: A pressure vessel is disclosed. The pressure vessel includes a continuous liner of corrugated material including a plurality of alternating main sections and intermediate sections. The main sections have a first diameter and the intermediate sections have a second diameter smaller than the first diameter. The pressure vessel also includes at least one reinforcing layer applied to an exterior of the continuous liner. The pressure vessel can be packaged in containers for modular use, with one or more containers being shaped to receive a portion of the reinforced continuous liner folded along one or more of the intermediate sections.

Abstract: An integrated dive suit includes at least one flexible polymeric pressure vessel connected with sections of flexible conduit to a manifold. The pressure vessel and sections of flexible conduit are encased in high strength fiber material. The pressure vessels are wrapped in high strength ballistic ribbon material. A weight system is integrated with the pressure vessels. The manifold provides connections for a high pressure regulator and an air fill source. A high pressure hose is connected to the high pressure regulator, a low pressure regulator is connected to the low pressure hose and a mouthpiece connected to the low pressure regulator. A hydrodynamic pressure vessel container is integrally attached to the dive suit. A two part, balanced flexible buoyancy control vest, flexible weight pellet containers and a wireless pressure gauge are integrated with the dive suit. A concentrator is used to pressurize a flexible pressure vessel for charging the vessels in the dive suit.

Abstract: An articulated firefighter breathing pack includes multiple polymeric pressure vessels connected together and to a flexible manifold with sections of flexible conduit. The pressure vessels and sections of flexible conduit are encased in high strength fiber material. The pressure vessels are wrapped in high strength ballistic ribbon material. The manifold provides connections for a high pressure regulator and an air fill source. A low pressure hose is connected to the high pressure regulator, a low pressure regulator is connected to the low pressure hose and a mouthpiece connected to the low pressure regulator. A pressure vessel container attaches the pressure vessels, the flexible conduit and the manifold to a harness having a waist portion and two vertical straps extending upwardly over the shoulders and back down to the waist portion. A utility belt provides mounting for equipment for the breathing pack including hoses, a power supply, electronic sensors and controls.

Abstract: An articulated firefighter breathing pack includes multiple polymeric pressure vessels connected together and to a flexible manifold with sections of flexible conduit. The pressure vessels and sections of flexible conduit are encased in high strength fiber material. The pressure vessels are wrapped in high strength ballistic ribbon material. The manifold provides connections for a high pressure regulator and an air fill source. A low pressure hose is connected to the high pressure regulator, a low pressure regulator is connected to the low pressure hose and a mouthpiece connected to the low pressure regulator. A pressure vessel container attaches the pressure vessels, the flexible conduit and the manifold to a harness having a waist portion and two vertical straps extending upwardly over the shoulders and back down to the waist portion. A utility belt provides mounting for equipment for the breathing pack including hoses, a power supply, electronic sensors and controls.

Abstract: A cellular reservoir flexible pressure vessel is formed as a series of closely packed tubes fitted into a pair of opposing end caps. The end caps have individual receptacles sized and shaped to receive the tube ends that are secured with adhesive or radio frequency welding. At least one end cap has a passageway for connection of the vessel. The flexible pressure vessel has a pressure relief device comprising a reduction in thickness of one end cap at a predetermined location. When subjected to overpressure it fails at the predetermined location. Other pressure relief devices include: a projecting member on the vessel surface, a weakened section of the passageway, a weakening or an absence of braiding material or hoop winding at a predetermined location on the vessel surface or along the passageway, a weakening or spreading of fibers in either the reinforcing panels or the flexible blankets covering the vessel.

Abstract: An ovoid flexible pressure vessel is described. At least one hollow pressure cell, formed of resilient material, a passageway, a valving means, a capillary tube, hoop winding, high-strength braiding material and at least one reinforcing ring are provided. The ovoid flexible pressure vessel has a pressure relief device comprising a reduction in thickness of the hollow pressure cell at a predetermined location whereby, when the hollow pressure cell is subjected to an overpressure condition it will fail at the predetermined location. Further pressure release devices include the following: a reduction in thickness of the cell, an indentation, a projecting member, a weakened section of the passageway, a weakening or an absence of high-strength braiding material or hoop winding at a predetermined location along the passageway, a weakening or spreading of fibers in either of the reinforcing panels or in either flexible blankets.

Abstract: A flexible pressure vessel is constructed from at least one pair of upper and mating lower dome shaped cell portions. The dome portions are molded from sheets of resilient material and joined together by radio frequency welding or high-strength adhesives. Upper and lower passageway portions extend outwardly from each cell portion to the surrounding sheet material. When the cell portions are joined the passageway portions are joined to form a passageway for connection to a valve or another cell. Upper and lower rings surround the upper and lower cell portions to provide reinforcement for the cells. First and second blankets of heavy-duty fiber reinforced material are attached over the upper and lower cell portions and stitched in place with heavy-duty stitching extending through the resilient material surrounding the cell portions. Cell shaped sponges impregnated with absorbent materials are encased in liquid and gas impermeable plastic tubing and inserted into the cells prior to joining of the cell portions.

Abstract: A cellular reservoir flexible pressure vessel is formed as a series of closely packed tubes fitted into a pair of opposing end caps. The end caps have individual receptacles sized and shaped to receive the tube ends that are secured with adhesive or radio frequency welding. At least one end cap has a passageway for connection of the vessel. The vessel may be formed in a variety of useful shapes and the tubes may have various internal and external cross-sections. The end caps may be filled with sintactic foam with canals leading to the passageway. Microtubes through the syntactic foam may connect the tubes to the passageway. The vessel is further strengthened by overwrapping with high-strength braiding material, hoop winding or by overlayment with high-strength fabric. The vessel is further strengthened by coating with plastic resin. Apparatus and methods for forming the cellular reservoir flexible vessels are described.

Abstract: A flexible pressure vessel is constructed from at least one pair of upper and mating lower dome shaped cell portions. Upper and lower passageway portions extend outwardly from each cell portion to surrounding sheet material. The portions are joined to form a passageway for connection to a valve or another cell. Upper and lower reinforcing rings surround the cell portions. Blankets of fiber reinforced material are attached over the cell portions and stitched in place through the surrounding resilient material. Cell shaped sponges impregnated with absorbent materials are encased in impermeable plastic tubing and inserted into the cells. High-strength filaments are wound around the tubing to provide additional pressure handling capability. Heat-reflecting plastic film or metal foil is inserted between blankets and the cell portions. Reinforcing rings are attached over and fastened through the blankets around the cells. An apparatus and method are described for constructing the flexible pressure vessel.

Abstract: A cellular reservoir flexible pressure vessel is formed as a series of closely packed tubes fitted into a pair of opposing end caps. The end caps have individual receptacles sized and shaped to receive the tube ends that are secured with adhesive or radio frequency welding. At least one end cap has a passageway for connection of the vessel. The flexible pressure vessel has a pressure relief device comprising a reduction in thickness of one end cap at a predetermined location. When subjected to overpressure it fails at the predetermined location. Other pressure relief devices include: a projecting member on the vessel surface, a weakened section of the passageway, a weakening or an absence of braiding material or hoop winding at a predetermined location on the vessel surface or along the passageway, a weakening or spreading of fibers in either the reinforcing panels or the flexible blankets covering the vessel.

Abstract: An ovoid flexible pressure vessel is described. At least one hollow pressure cell, formed of resilient material, a passageway, a valving means, a capillary tube, hoop winding, high-strength braiding material and at least one reinforcing ring are provided. The ovoid flexible pressure vessel has a pressure relief device comprising a reduction in thickness of the hollow pressure cell at a predetermined location whereby, when the hollow pressure cell is subjected to an overpressure condition it will fail at the predetermined location. Further pressure release devices include the following: a reduction in thickness of the cell, an indentation, a projecting member, a weakened section of the passageway, a weakening or an absence of high-strength braiding material or hoop winding at a predetermined location along the passageway, a weakening or spreading of fibers in either of the reinforcing panels or in either flexible blankets.

Abstract: A flexible pressure vessel is constructed from at least one pair of upper and mating lower dome shaped cell portions. The dome portions are molded from sheets of resilient material and joined together by radio frequency welding or high-strength adhesives. Upper and lower passageway portions extend outwardly from each cell portion to the surrounding sheet material. When the cell portions are joined the passageway portions are joined to form a passageway for connection to a valve or another cell. Upper and lower rings surround the upper and lower cell portions to provide reinforcement for the cells. First and second blankets of heavy-duty fiber reinforced material are attached over the upper and lower cell portions and stitched in place with heavy-duty stitching extending through the resilient material surrounding the cell portions. Cell shaped sponges impregnated with absorbent materials are encased in liquid and gas impermeable plastic tubing and inserted into the cells prior to joining of the cell portions.

Abstract: A cellular reservoir flexible pressure vessel is formed as a series of closely packed tubes fitted into a pair of opposing end caps. The end caps have individual receptacles sized and shaped to receive the tube ends that are secured with adhesive or radio frequency welding. At least one end cap has a passageway for connection of the vessel. The vessel may be formed in a variety of useful shapes and the tubes may have various internal and external cross-sections. The end caps may be filled with sintactic foam with canals leading to the passageway. Microtubes through the syntactic foam may connect the tubes to the passageway. The vessel is further strengthened by overwrapping with high-strength braiding material, hoop winding or by overlayment with high-strength fabric. The vessel is further strengthened by coating with plastic resin. Apparatus and methods for forming the cellular reservoir flexible vessels are described.

Abstract: A flexible pressure vessel is constructed from at least one pair of upper and mating lower dome shaped cell portions. The dome portions are molded from sheets of resilient material and joined together by radio frequency welding or high-strength adhesives. Upper and lower passageway portions extend outwardly from each cell portion to the surrounding sheet material. When the cell portions are joined the passageway portions are joined to form a passageway for connection to a valve or another cell. Upper and lower rings surround the upper and lower cell portions to provide reinforcement for the cells. First and second blankets of heavy-duty fiber reinforced material are attached over the upper and lower cell portions and stitched in place with heavy-duty stitching extending through the resilient material surrounding the cell portions. Cell shaped sponges impregnated with absorbent materials are encased in liquid and gas impermeable plastic tubing and inserted into the cells prior to joining of the cell portions.

Abstract: An apparatus for forming a polymeric pressure vessel includes two, coaxial plastic extruders separated by a hole-forming laser and connected to a variable die, a vacuum/blow molding apparatus, a fusing device, a braiding mechanism, and an overcoat applicator. The first extruder forms a tubular core, and the laser forms axially-spaced apertures in the core. The second extruder forms an outer tube coaxially over the tubular core and the variable die is alternately opened and closed to form parisons of increased material at axially-spaced locations along the outer tube. The parisons are moved into the molding apparatus and are expanded in a vacuum/blow molding process into hollow chambers of preferably ellipsoidal shape. The fusing device fuses the outer tube to the tubular core at locations between the spaced-apart hollow chambers, the braiding mechanism then applies a layer of interwoven reinforcing filament fiber, and the overcoat applicator applies a protective polymeric coating over the fiber layer.

Abstract: A litter for carrying a patient in a supine position, such as a stretcher or trauma board, includes a support panel and a pressure pack for providing a portable supply of medicinal gas, such as oxygen, that can be administered to a patient on the liter. The pressure pack includes a gas storage vessel formed from a plurality of polymeric hollow chamber having either en ellipsoidal or spherical shape and interconnected by a plurality of relatively narrow conduit sections disposed between consecutive ones of the chambers. The storage vessel includes a reinforcing filament wrapped around the interconnected chambers and interconnecting conduit sections to limit radial expansion of the chambers and conduit sections when filled with a fluid under pressure.

Abstract: A vehicle includes a storage pack for storing gas under pressure for providing an onboard supply of the pressurized gas. The pressurized gas may be used as a medicinal gas, e.g. oxygen, on emergency medical vehicles, or the gas may be used as a fuel source for a motorized vehicle having a motor that runs on combustible gas. The gas storage pack includes a pressure vessel formed from a plurality of hollow chambers, which have either an ellipsoidal or spherical shape, interconnected by a plurality of relatively narrow conduit sections disposed between consecutive ones of the chambers. The pressure vessel includes a reinforcing filament wrapped around the interconnected chambers and interconnecting conduit sections to limit radial expansion of the chambers and conduit sections when filled with a fluid under pressure. The gas storage pack further includes a gas transfer control system attached to the pressure vessel for controlling gas flow into and out of the pressure vessel.

Abstract: A utility belt includes a gas storage vessel for providing a portable and ambulatory supply of oxygen for the person wearing the belt or a person being attended to by the person wearing the belt. In particular, the utility belt provides a portable supply of pressurized gas while it is suspended from the body of a user, with a plurality of item holders, such as implement holsters and utility pouches, suspended from the utility belt. The supply of pressurized gas is provided by a gas storage vessel carried on the utility belt. The gas storage vessel is formed from a plurality of polymeric hollow chamber having either an ellipsoidal or spherical shape and interconnected by a plurality of relatively narrow conduit sections disposed between consecutive ones of the chambers. The gas storage vessel includes a reinforcing filament wrapped around the interconnected chambers and interconnecting conduit sections to limit radial expansion of the chambers and conduit sections when filled with a fluid under pressure.