The invention relates to a composition for generating oxygen, comprising at least one oxygen source, and at least one ionic liquid comprising a cation and an anion, wherein the oxygen source is a peroxide compound, the ionic liquid is in the liquid state at least in a temperature range from 10 C. to +50 C., and the anion is selected from metallate anions.

A portable oxygen-generating breathing apparatus comprising a user interface configured to receive an exhalation air stream from and supply a breathable inhalation air stream to a user, a reaction chamber configured to house a reaction composition that reacts with the exhalation air stream in order to convert the exhalation air stream into the breathable inhalation air stream, an inflatable member configured to receive the breathable inhalation air stream from the reaction chamber, and an interface junction disposed between the user interface and the reaction chamber in a flow direction of the exhalation air stream and between the inflatable member and the user interface in a flow direction of the breathable inhalation air stream, the interface junction having an exhale valve to allow the flow of the exhalation air stream and an inhale valve to allow the flow of the breathable inhalation air stream one-directionally.

A portable oxygen-generating breathing apparatus comprising a user interface configured to receive an exhalation air stream from and supply a breathable inhalation air stream to a user, a reaction chamber configured to house a reaction composition that reacts with the exhalation air stream in order to convert the exhalation air stream into the breathable inhalation air stream, an inflatable member configured to receive the breathable inhalation air stream from the reaction chamber, and an interface junction disposed between the user interface and the reaction chamber in a flow direction of the exhalation air stream and between the inflatable member and the user interface in a flow direction of the breathable inhalation air stream, the interface junction having an exhale valve to allow the flow of the exhalation air stream and an inhale valve to allow the flow of the breathable inhalation air stream one-directionally.

A compact ignition system for chemical oxygen generators for possible use in an aircraft. The chemical oxygen generator is configured such that a majority of the ignition system can be accommodated within an interior of the generator body. In some embodiments, the ignition system is positioned within a recess of an upper surface of the core of the generator. Housing a majority of the ignition system within the generator allows the overall oxygen-generating capacity of the generator to be increased without requiring a corresponding increase in the overall length of the generator.

A compact ignition system for chemical oxygen generators for possible use in an aircraft. The chemical oxygen generator is configured such that a majority of the ignition system can be accommodated within an interior of the generator body. In some embodiments, the ignition system is positioned within a recess of an upper surface of the core of the generator. Housing a majority of the ignition system within the generator allows the overall oxygen-generating capacity of the generator to be increased without requiring a corresponding increase in the overall length of the generator.

A portable oxygen generating system is provided that comprises a reaction chamber, a feed system for providing and controlling hydrogen peroxide solution to the reaction chamber, and a cooling/condensing system for cooling the hot oxygen and water vapor leaving the reactor and condensing and removing water. The portable chemical oxygen generation system produces humidified, breathable oxygen, that is substantially free of hydrogen peroxide and other contaminants, at a controlled flow and temperature over an extended period of time.

A portable oxygen generating system is provided that comprises a reaction chamber, a feed system for providing and controlling hydrogen peroxide solution to the reaction chamber, and a cooling/condensing system for cooling the hot oxygen and water vapor leaving the reactor and condensing and removing water. The portable chemical oxygen generation system produces humidified, breathable oxygen, that is substantially free of hydrogen peroxide and other contaminants, at a controlled flow and temperature over an extended period of time.

A method for monitoring generation of dust in a self-contained breathing apparatus involves performing a preliminary empirical compilation of databases related to an amount of dust that results from vibrations and/or mechanical impacts; determining a total empirical amplitude value; registering vibrations and/or mechanical impacts on a self-contained breathing apparatus under actual operating conditions; comparing a total breathing apparatus amplitude value with the total empirical amplitude value; generating a signal of inoperability when the dust content value exceeds a preset maximum allowable value. A monitoring device comprises a three-axis accelerometer and microcontroller configured to convert acceleration vectors into the total breathing apparatus amplitude value and compare this value the total empirical amplitude value. The device generates a signal of inoperability when the dust content value exceeds the preset maximum allowable value. The monitoring device may be part of a monitoring system comprising multiple breathing apparatuses and monitoring devices.

A method for monitoring generation of dust in a self-contained breathing apparatus involves performing a preliminary empirical compilation of databases related to an amount of dust that results from vibrations and/or mechanical impacts; determining a total empirical amplitude value; registering vibrations and/or mechanical impacts on a self-contained breathing apparatus under actual operating conditions; comparing a total breathing apparatus amplitude value with the total empirical amplitude value; generating a signal of inoperability when the dust content value exceeds a preset maximum allowable value. A monitoring device comprises a three-axis accelerometer and microcontroller configured to convert acceleration vectors into the total breathing apparatus amplitude value and compare this value the total empirical amplitude value. The device generates a signal of inoperability when the dust content value exceeds the preset maximum allowable value. The monitoring device may be part of a monitoring system comprising multiple breathing apparatuses and monitoring devices.

The invention relates to an aircraft passenger emergency oxygen supply device comprising an oxygen mask having a mask body with a first opening for covering mouth and/or nose of the passenger, a second opening connecting said first opening with a source of oxygen, a passenger service unit, a connecting line fixed to the oxygen mask body at one end and having a coupling at the other end for coupling said line to the passenger service unit wherein a chemical reaction component is comprised in the oxygen mask.