An emergency elevator includes a door frame installed on upper, left and right sides of an entrance of an elevator platform, an elevator car configured to vertically move along an elevator passage and provided with a pair of elevator doors, a pair of platform doors installed in the door frame, a lower frame installed on a lower side of the entrance of the elevator platform and configured to slidably support the platform doors, an upper door rim installed on an upper side of the platform doors, a side door rim vertically installed at a lateral end of the platform doors, an oxygen supply device configured to supply oxygen to a patient in the elevator car, an emergency ventilation device configured to supply a purified air into the elevator car, and a filter device provided in the blowing duct so as to remove harmful substances introduced into the elevator car.

An emergency elevator includes a door frame installed on upper, left and right sides of an entrance of an elevator platform, an elevator car configured to vertically move along an elevator passage and provided with a pair of elevator doors, a pair of platform doors installed in the door frame, a lower frame installed on a lower side of the entrance of the elevator platform and configured to slidably support the platform doors, an upper door rim installed on an upper side of the platform doors, a side door rim vertically installed at a lateral end of the platform doors, an oxygen supply device configured to supply oxygen to a patient in the elevator car, an emergency ventilation device configured to supply a purified air into the elevator car, and a filter device provided in the blowing duct so as to remove harmful substances introduced into the elevator car.

An oxygen generator is provided. The oxygen generator includes a generator case comprising at least two hollow chambers, at least two cartridges housed within the corresponding at least two hollow chambers. Each of the at least two cartridges include a water chamber, a chemical chamber, a holding means mechanically coupled to an interior top portion of the at least two cartridges, a triggering means mechanically held in place by the holding means. The triggering means include a top seal configured to unlock a bottom seal upon twisting a trigger connector, a trigger valve, a hollow seal tube located along a central axis of the corresponding at least two cartridges, the bottom seal configured to allow a pre-defined amount of water to enter the chemical chamber via a filter. The hollow seal tube is configured to allow flow of oxygen generated in the chemical chamber.

An oxygen generator is provided. The oxygen generator includes a generator case comprising at least two hollow chambers, at least two cartridges housed within the corresponding at least two hollow chambers. Each of the at least two cartridges include a water chamber, a chemical chamber, a holding means mechanically coupled to an interior top portion of the at least two cartridges, a triggering means mechanically held in place by the holding means. The triggering means include a top seal configured to unlock a bottom seal upon twisting a trigger connector, a trigger valve, a hollow seal tube located along a central axis of the corresponding at least two cartridges, the bottom seal configured to allow a pre-defined amount of water to enter the chemical chamber via a filter. The hollow seal tube is configured to allow flow of oxygen generated in the chemical chamber.

Disclosed is a chemical oxygen self-rescue device, comprising a breathing assembly (1), an oxygen generating assembly (2) and a gas bag (3) sequentially communicated with each other, wherein the oxygen generating assembly comprises an oxygen generating agent tank (21), a gas discharge valve (23) and an oxygen candle (22); the gas discharge valve is arranged on a component above an oxygen generating agent (213) in the oxygen generating agent tank and below a breathing end of the breathing assembly, and the opening and closing of the gas discharge valve are controlled by means of an inflated volume of the gas bag; and a heat radiation assembly and the oxygen generating agent are provided in the oxygen generating agent tank, the heat radiation assembly comprises a vent pipe (211) and a heat radiation frame (212), the vent pipe communicates the breathing assembly with the oxygen generating agent tank, the heat radiation frame is provided in the oxygen generating agent tank, and the oxygen generating agent tank is divided, by the vent pipe and the heat radiation frame, into a plurality of accommodation spaces for the loading of the oxygen generating agent. The chemical oxygen self-rescue device reduces the resistance to breathing, lowers the temperature of breathed gas and improves the utilization rate of the oxygen generating agent.

Disclosed is a chemical oxygen self-rescue device, comprising a breathing assembly (1), an oxygen generating assembly (2) and a gas bag (3) sequentially communicated with each other, wherein the oxygen generating assembly comprises an oxygen generating agent tank (21), a gas discharge valve (23) and an oxygen candle (22); the gas discharge valve is arranged on a component above an oxygen generating agent (213) in the oxygen generating agent tank and below a breathing end of the breathing assembly, and the opening and closing of the gas discharge valve are controlled by means of an inflated volume of the gas bag; and a heat radiation assembly and the oxygen generating agent are provided in the oxygen generating agent tank, the heat radiation assembly comprises a vent pipe (211) and a heat radiation frame (212), the vent pipe communicates the breathing assembly with the oxygen generating agent tank, the heat radiation frame is provided in the oxygen generating agent tank, and the oxygen generating agent tank is divided, by the vent pipe and the heat radiation frame, into a plurality of accommodation spaces for the loading of the oxygen generating agent. The chemical oxygen self-rescue device reduces the resistance to breathing, lowers the temperature of breathed gas and improves the utilization rate of the oxygen generating agent.

A patient interface of a respiratory therapy system is provided, and comprises: a. a mask body; b. a mask seal secured to the mask body and configured to form a seal with the user's face, at least around the user's mouth; the mask body and mask seal being arranged to define an interior breathing chamber of the patient interface; and c. an inlet to the breathing chamber configured to receive a flow of breathable gases into the breathing chamber. To assist in allowing a user to speak clearly whilst wearing/using the patient interface, a user actuatable speech valve is provided on the patient interface and is operable to selectively occlude and open a speech flow path from the breathing chamber to atmosphere when the user wishes to speak.

A patient interface of a respiratory therapy system is provided, and comprises: a. a mask body; b. a mask seal secured to the mask body and configured to form a seal with the user's face, at least around the user's mouth; the mask body and mask seal being arranged to define an interior breathing chamber of the patient interface; and c. an inlet to the breathing chamber configured to receive a flow of breathable gases into the breathing chamber. To assist in allowing a user to speak clearly whilst wearing/using the patient interface, a user actuatable speech valve is provided on the patient interface and is operable to selectively occlude and open a speech flow path from the breathing chamber to atmosphere when the user wishes to speak.

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.

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.