Disclosed is a headgear-type device for hazardous air quality warning and air quality improvement, wherein the device can collect biometric information of a worker, wired and wireless communications, and information about the quality of outside air around the worker so as to warn the worker of a hazard or improve air quality at the site. The headgear-type device for hazardous air quality warning and air quality improvement according to the present invention may comprise: a headgear-type biometric sensor which comes into close contact with the head of the worker so as to sense biometric information of the worker and thus allow measurements of the worker's physical conditions; a terminal which is wiredly or wirelessly connected to the headgear-type biometric sensor so as to transmit and receive the biometric information; and a server which receives the biometric information from the terminal, calculates, on the basis thereof, whether the biometric information is in a normal condition range, according to a program, and when the biometric information is not in the normal condition range, issues a warning to the worker by transmitting a warning state to the terminal.

A vented anti-contaminant device and more specifically to a wearable device incorporating a conduit network that uses sorption to protect users against viral, bacterial, fungal, protozoan, microbial, particulate, and xenobiotic contaminants is disclosed. In one embodiment, a wearable protective device, comprising: a breathing chamber; a conduit network attached to the breathing chamber at a first conduit network terminal portion such that the breathing chamber is in fluid communication with the first conduit network terminal portion; a second conduit network terminal portion of the conduit network in fluid communication with an air source; and a sorption structure within the conduit network is disclosed.

A vented anti-contaminant device and more specifically to a wearable device incorporating a conduit network that uses sorption to protect users against viral, bacterial, fungal, protozoan, microbial, particulate, and xenobiotic contaminants is disclosed. In one embodiment, a wearable protective device, comprising: a breathing chamber; a conduit network attached to the breathing chamber at a first conduit network terminal portion such that the breathing chamber is in fluid communication with the first conduit network terminal portion; a second conduit network terminal portion of the conduit network in fluid communication with an air source; and a sorption structure within the conduit network is disclosed.

An embodiment of a positive pressure loose-fitting head device, such as a hood, helmet or headgear, with exhaustion conduit directing exhaust into user's PPE is shown; there may be an outflow/exhaust drain; there may be a outflow/exhaust tube/conduit under shroud into PPE; there may be connections for add-ons (controls, dampers, valves, diffusers, filters . . . ); there may be an outer shroud and an inner shroud; there may be purified air from power unit; there may be an inflow location.

An embodiment of a positive pressure loose-fitting head device, such as a hood, helmet or headgear, with exhaustion conduit directing exhaust into user's PPE is shown; there may be an outflow/exhaust drain; there may be a outflow/exhaust tube/conduit under shroud into PPE; there may be connections for add-ons (controls, dampers, valves, diffusers, filters . . . ); there may be an outer shroud and an inner shroud; there may be purified air from power unit; there may be an inflow location.

A breathing apparatus may include a heater configured to kill harmful organisms in air. The apparatus may include a vest, including a heating chamber disposed on the vest and a cooling chamber disposed on the vest. The heating chamber may include a heat source, and the heat source may heat air disposed within the heating chamber to a predetermined temperature. The heating chamber and the cooling chamber may be in fluid communication. The apparatus may include a breathing tube, including a first end and a second end. The first end may connect to the cooling chamber. The apparatus may include a breathing mask. The second end of the breathing tube may connect to the breathing mask. The cooling chamber and the breathing mask may be in fluid communication via the breathing tube.

A breathing apparatus may include a heater configured to kill harmful organisms in air. The apparatus may include a vest, including a heating chamber disposed on the vest and a cooling chamber disposed on the vest. The heating chamber may include a heat source, and the heat source may heat air disposed within the heating chamber to a predetermined temperature. The heating chamber and the cooling chamber may be in fluid communication. The apparatus may include a breathing tube, including a first end and a second end. The first end may connect to the cooling chamber. The apparatus may include a breathing mask. The second end of the breathing tube may connect to the breathing mask. The cooling chamber and the breathing mask may be in fluid communication via the breathing tube.

The invention relates to a system to deliver a respiratory gas to crew members in a cabin of an aircraft. The system includes at least one respiratory mask, an ambient air inlet for admission of ambient air into the respiratory mask, a source of additional gas, supply lines to transport the additional gas to the respiratory mask, a mixing chamber provided on the supply lines to mix the additional gas with ambient air to supply a respiratory gas corresponding to a mixture of the additional gas and the ambient air to the respiratory mask, regulation system to regulate the additional gas content of the respiratory gas at least partly as a function of the aircraft altitude.

The invention relates to a system to deliver a respiratory gas to crew members in a cabin of an aircraft. The system includes at least one respiratory mask, an ambient air inlet for admission of ambient air into the respiratory mask, a source of additional gas, supply lines to transport the additional gas to the respiratory mask, a mixing chamber provided on the supply lines to mix the additional gas with ambient air to supply a respiratory gas corresponding to a mixture of the additional gas and the ambient air to the respiratory mask, regulation system to regulate the additional gas content of the respiratory gas at least partly as a function of the aircraft altitude.

A personal protected-air system includes a ring adapted to fit over a user's head. The ring includes a port for receiving breathable air, a manifold in fluid communication with the port, and vents in fluid communication with the manifold. The vents are distributed about a portion of the ring. A face mask is coupled to the ring. The face mask has a first edge, a second edge, and mask material extending from the first edge to the second edge. The first edge is coupled to the ring adjacent to the portion thereof where the vents are so-distributed. The second edge is adapted to fit snugly against the user's cheeks and nose bridge wherein the mask material is spaced apart from the user's nostrils and mouth by an air space and wherein the breathable air enters the air space via the vents