Detection of unintentional air leaks in a user interface (e.g., mask) of a respiratory therapy system (e.g., a positive air pressure device) is disclosed. One or more sensors (e.g., within a computing device, such as a smartphone) can be moved around relative to the user interface to determine a location and/or intensity of an air leak. The computing device can provide feedback regarding the location and/or intensity of the air leak to facilitate the user locating the air leak, and thus correcting the air leak. In some cases, augmented reality annotations can be overlaid on an image (e.g., live image) of the user wearing the user interface to identify the location of the air leak. The system can automatically detect the type of user interface being used and can provide tailored guidance for reducing the air leaks.

A breath detection apparatus for monitoring individual breaths of a patient. The apparatus includes a sensing assembly comprising a humidity sensor. The sensing assembly adapted to be connected to an oxygenation device wherein respiratory gases of a patient are directed over the sensing assembly and the humidity sensor is adapted to monitor differences in humidity during a breath of the patient. The humidity sensor generates an electrical signal representing a humidity level in response to measuring the humidity during the breath. The apparatus also includes a processor in electrical communication with the sensing assembly to receive electrical signals generated by the humidity sensor and determine a state of the relative humidity during the breath, and a visual display element controlled by the processor and adapted to display a predetermined visual alert in response to the state of the relative humidity during the breath.

A respiratory apparatus comprising a base and removable chamber, wherein the chamber is configured to hold a supply of water and include a blower arrangement adapted to provide a supply of pressurized air or gas to the supply of water. In certain embodiments the respiratory apparatus includes a split motor, wherein the stationary components are located within a base and the rotating portions are located within a chamber.

A method of a control system (2200) controls an inductance motor in a blower including an impeller and volute using a pressure compensation control system. The control system may be implemented in a respiratory pressure therapy device. The control system may include a sensor configured to provide a pressure signal indicative of the pressure of a flow of fluid produced by the blower. A measured pressure may be compared to a set pressure to determine a pressure error. A slip frequency may be adjusted as a function of the pressure error in an attempt to eliminate or minimise the pressure error.

A personal entertainment respiratory apparatus provides air to a user to provide a fully immersive entertainment experience. The personal entertainment system may comprise a flow generator for providing the flow of air. A personal spatial respiratory interface may be coupled to the flow generator. The personal spatial respiratory interface may comprise an outlet for the flow generator. The personal spatial respiratory interface may further be configured to direct the flow of air within an ambient breathing proximity of a user. The personal entertainment respiratory apparatus may further comprise a controller and a sensory particle dispenser. The controller and sensory particle dispenser may be configured to selectively activate release of a sensory particle from the dispenser into the directed flow of air in response to an entertainment triggering signal.

Disclosed is an autoCPAP respirator which comprises a control unit, a respiration blower and a pressure sensor. The control unit comprises a controller for generating a first control signal, which induces the speed of the blower to generate a pressurized breathing gas flow, a controller for generating a periodically variable control signal, which activates the blower such that the speed of the blower varies in an oscillating manner at a frequency in the range of 1-20 Hz, and a sensor device, which ascertains one or more of instantaneous speed, instantaneous electrical current and instantaneous electrical power of the blower to determine the breathing gas flow and/or breathing gas volume generated by the blower while using characteristic data of the blower stored in a memory.

An inhaler comprises a housing, an air channel extending between at least one air inlet opening and a suction opening in the housing, a dispensing element for vaporizing or nebulizing liquid supplied to the dispensing element for admixing with air flowing in the air channel, an electronic control device, an electronic data memory, and a sensor system comprising a flow measuring device for measuring the volumetric and/or mass flow of air flowing through the air channel. The electronic control device is adapted to capture a plurality of airflow measurement values over at least a portion of the duration of an inhalation puff by means of the flow measurement device, compare the plurality of airflow measurement values to a puff profile stored in the data memory, and output a control signal based on the comparison of the plurality of airflow measurement values to the stored puff profile.

The present disclosure relates to a method for identifying a user interface. Flow data associated with air flowing in a respiratory therapy system is received. Acoustic data associated with the respiratory therapy system is received. The received flow data and the received acoustic data are analyzed. Based at least in part on the analysis, a mask type for the user interface is determined.

A method of predicting an unintentional leak in a respiratory system during a sleep session includes causing, during the sleep session, pressurized air to be delivered from a respiratory device to a user via a conduit coupled to a user interface. The method also includes receiving historical first data associated with pressurized air delivered from the respiratory device during one or more prior sleep sessions; receiving current first data associated with the pressurized air being delivered from the respiratory device during the sleep session; receiving historical second data associated with the user during one or more prior sleep sessions; and receiving, via one or more second sensors, current second data associated with the user during the current sleep session. The method determines, a likelihood that an unintentional leak in the respiratory system will occur within a predetermined amount of time.

A humidification system including a conduit for carrying breathing gases, a pump to pressurize a liquid for injection into breathing gases, a liquid-injection nozzle protruding at least partially into the conduit and configured to inject liquid, pressurized by the pump, into the conduit; and a heated surface protruding into the conduit and positioned to vaporize the liquid injected by the nozzle, wherein the heated surface crosses a flow path of the breathing gases flowing through the conduit.