A diving apparatus for a diver underwater includes a portable habitat in which a breathable environment is maintained underwater. The habitat has a collapsible envelope. The collapsible envelope takes shape through inflation to an expanded state underwater. The habitat has a modular payload which removably attaches to the envelope underwater. The habitat has a seat on which a diver can sit while the habitat is underwater. The modular payload has a breathable gas source to provide breathable gas for the diver to breathe in the habitat and a carbon dioxide scrubber which removes carbon dioxide from the environment when the habitat is underwater. The apparatus has an anchor mechanism attached to the habitat to maintain the habitat at a desired depth underwater. A method for a diver to dive underwater. A system for supporting a diver underwater. A diving apparatus having a propulsion unit. An apparatus for a user in outer space or on another planet.

The present invention comprises a snorkel, comprising a breathing hose, the breathing hose having a mouthpiece at one end and connected to a buoyant rigid body at the other end, the rigid body comprising an internal cavity, with the breathing hose connected to the internal cavity; a first opening into the internal cavity disposed at a top end of the rigid body, the first opening having a first cover with a diameter greater than the diameter of the opening, and the first cover extending over the first opening; and a weighted ring secured to a bottom end of the rigid body, the weighted ring surrounding the end of the breathing hose connected to the rigid body, wherein the breathing tube and the first opening define an airway permitting a user to breathe through the snorkel.

A pressure reducing second stage for underwater use includes a case provided with a breathing gas inlet, with an inhalation/exhalation port and with an exhaled gas exhaust outlet with a non-return valve, the gas inhalation/exhalation port being connected to a mouthpiece tube, the breathing gas inlet in the case being connected to a breathing gas pressure reducing device provided with a hollow cylindrical element or pipe, which has a breathing gas inlet port communicating with a gas supply conduit through a valve which is interposed between the supply conduit and the mouthpiece tube, the case being provided with a pressure sensitive means device for controlling the opening/closure of the valve. The breathing gas inlet in the case is provided in its lower portion and the hollow cylindrical element is connected to the inlet on the case such that its axis is substantially vertical, when used in the upright position.

Swim cap comprising a respirator, ear pockets housing headphones, a communication system comprising a microphone integrated in a mouthpiece and a wireless audio/voice communication system for enabling voice communication while swimming and avoiding turning the head to lift it out of the water to breathe.

A modular manifold assembly is configured to connect to a manifold block of an auto cascade system used to fill an individual fluid tank. The modular manifold assembly may include a main housing that contains one or more sequence valves and fluid conduits. The sequence valve(s) are configured to allow fluid to be sequentially drawn from a plurality of fluid storage cylinders.

A system is designed to increase diver safety in a high-risk environment containing one or more hazardous materials. The system includes chemically-hardened surface-supplied diving equipment designed to provide full environment isolation for the diver. The system also includes a dive helmet and a surface-return exhaust system, where the surface-return exhaust system includes a demand exhaust regulator that serves as a pressure-actuated valve to enable exhausting to a breathable atmosphere outside of a dive helmet instead of exhausting into the environment containing one or more hazardous materials. The system also includes retrofittable kits enabling the upgrading of contaminant-vulnerable materials of an existing dive helmet. The system also includes fluoroelastomeric materials and components to implement in a closed circuit dive system.

A system is designed to increase diver safety in a high-risk environment containing one or more hazardous materials. The system includes chemically-hardened surface-supplied diving equipment designed to provide full environment isolation for the diver. The system also includes a dive helmet and a surface-return exhaust system, where the surface-return exhaust system includes a demand exhaust regulator that serves as a pressure-actuated valve to enable exhausting to a breathable atmosphere outside of a dive helmet instead of exhausting into the environment containing one or more hazardous materials. The system also includes retrofittable kits enabling the upgrading of contaminant-vulnerable materials of an existing dive helmet. The system also includes fluoroelastomeric materials and components to implement in a closed circuit dive system.

A miniature breathing device for underwater breathing that can be worn on a person during water activities. A small form factor and lightweight housing suitable for submerging in shallow water. The small form factor preventing disruption of activities of a user undertaken while wearing the miniature breathing device. A canister within the housing stores a mixture of compressed air. An actuator on the housing to controllably releases the compressed air from the canister. A regulator piston within the housing is shaped with chambers to decompress the compressed air to breathable form. A mouthpiece opening of the housing provides breathable air to lips of a user. A strap secures the miniature breathing device to the user during activities.

A miniature breathing device for underwater breathing that can be worn on a person during water activities. A small form factor and lightweight housing suitable for submerging in shallow water. The small form factor preventing disruption of activities of a user undertaken while wearing the miniature breathing device. A canister within the housing stores a mixture of compressed air. An actuator on the housing to controllably releases the compressed air from the canister. A regulator piston within the housing is shaped with chambers to decompress the compressed air to breathable form. A mouthpiece opening of the housing provides breathable air to lips of a user. A strap secures the miniature breathing device to the user during activities.

An underwater breathing apparatus includes an elastic interior bag designed to hold air. The interior bag is contained within an outer container, which is designed to hold a weighted material which functions to offset positive buoyancy created by the air in the interior bag. The elasticity of the interior bag, as well as a slider mechanism, functions to provide pressure such that the air is accessible to a human diver while underwater. The apparatus also contains a pump that is used to fill the interior bag with air, and a mouthpiece that functions to allow the user to draw air from the apparatus.