A valve arrangement includes a first member formed from a pliable material, the first member having at least one aperture defined therethrough. The valve arrangement also includes a second member coupled to the first member, the second member formed from another pliable material. The second member is movable from: a first position in which the second member is sealingly engaged about a periphery of the at least one aperture, thus preventing passage of a fluid through the aperture, and a second position in which at least a portion of the second member is spaced from the periphery of the aperture such that the fluid is able to pass through the aperture.

The present disclosure relates to a ventilation valve configured to be mounted to a liquid reservoir of an electronic atomizing device. The ventilation valve includes: a valve sleeve connected to the liquid reservoir and provided with a through hole, the through hole in communication with a storage cavity of the liquid reservoir; and a valve element having air permeability and including an oleophobic material layer adjacent to the storage cavity, and a semi-permeable membrane connected to an end of the oleophobic material layer away from the storage cavity, the oleophobic material layer filling at least a part of the through hole.

A mobile oxygen point of use apparatus includes a standalone and portable mounting panel having a first side and a second side and is configured to be portably relocated within a facility by at least one human operator. A first set of oxygen flow regulators are mounted on the first side of the mounting panel and have multiple first oxygen inputs and multiple first oxygen outputs. A second set of oxygen flow regulators are mounted on the second side of the mounting panel and have multiple second oxygen inputs and multiple second oxygen outputs. A low pressure oxygen input is mounted on the mounting panel and a single pipeline or hose is configured to be connected from the low pressure oxygen input to a source of oxygen. Distribution plumbing connects the low pressure oxygen input to the multiple first oxygen inputs and the multiple second oxygen inputs.

A ventilator, including: a housing; a reservoir within the housing, wherein the reservoir has an internal chamber, an air inlet port, configured to place in fluid communication the internal chamber with atmospheric air, and an oxygen inlet port, configured to place in fluid communication the internal chamber with a source of oxygen; and a primary blower having an air inlet in fluid communication with the internal chamber, and an air outlet configured to be placed in fluid communication with an inspiration tube external of the ventilator housing, wherein the internal chamber presents a volume for gas mixing extending at least between the air inlet port, the oxygen inlet port and the primary blower air inlet, said volume configured for allowing mixing of air entering in the reservoir via the air inlet port with oxygen entering via the oxygen inlet port before any gas reaches the primary blower air inlet.

A resuscitation management system for a manual resuscitator. The resuscitation management system includes a flex sensor and a processor. The flex sensor is configured to be attached to a resuscitation bag of the manual resuscitator, conform a shape of the resuscitation bag during compression/decompression of the resuscitation bag, measure an amount of bending of the flex sensor, generate an output signal indicative of the amount of bending of the flex sensor. The processor receives a plurality of output signals from the flex sensor and calculate a breathing rate by counting the delivered ventilations during a time interval.

The present invention relates to adjustable flow control valves, for example to an Adjustable Pressure Limiting (APL) valve. The adjustable valve (2) described comprises a valve body (4) comprising a valve seat (6), a valve member (10) movable relative to the valve seat (6), a first valve cap (20), a second valve cap (50) and a biasing element (30) to bias the valve member (10) away from the first valve cap (20). The first valve cap (20) is movable to increase the biasing force applied by the biasing element (30). The second valve cap (50) is engageable with the first valve cap (20) to prevent such movement of the first valve cap (20) beyond a selected position, but to allow movement of the first valve cap (20) in an opposite direction, way from said position.

A system and method for controlling a flow is disclosed. The system includes an inlet channel (100, 310) and an outlet channel (200, 320). The inlet channel has an inlet port at a first end configured to be connected to a patient, and a second end with an at least part-annularly shaped aperture (314). The outlet channel has an outlet port at a first end, and an aperture (313) at a second end. The system further comprises a flow channel arranged concentrically outside the at least part-annularly shaped aperture. The flow channel is in fluid connection with the outlet channel. The at least part-annularly shaped aperture of the inlet channel and the aperture of the outlet channel are separated by a seating means (312). The at least part-annularly shaped aperture of the inlet channel and the flow channel are separated by the seating means.

A ventilator including a housing having a front panel, and a rear panel opposite the front panel and configured to couple to the front panel, a receptacle coupled to the rear panel of the housing, the receptacle having a recess, a sealing element disposed within the recess, the sealing element having an inlet and an aperture, and a blower having a blower outlet and a blower inlet, the blower inlet coupled to the sealing element such that the blower inlet at least partially abuts the aperture. The receptacle and the sealing element may comprise an airflow pathway configured to allow for flow of air from the inlet of the sealing element into the blower inlet and out of the blower outlet.

A process for ventilating a patient as well as a devicepatient module (20)operating according to the process, wherein, for example, a body weight value concerning an estimated body weight of the patient is transmitted to a patient module (20) intended for ventilating the patient, wherein the patient module (20) automatically selects ventilation parameters (52) fitting the body weight value on the basis of the body weight value and wherein the ventilation of the patient is carried out with the selected ventilation parameters (52).

An exchanger conduit permits temperature and/or humidity conditioning of a gas for a patient respiratory interface. In an example embodiment, a conduit has a first channel and a second channel where the first channel is configured to conduct an inspiratory gas and the second channel configured to conduct an expiratory gas. An exchanger is positioned along the first channel and the second channel to separate the first channel and the second channel. The exchanger is configured to transfer a component (e.g., temperature or humidity) of the gas of the second channel to the gas of the first channel. In some embodiments, an optional flow resistor may be implemented to permit venting at pressures above atmospheric pressure so as to allow pressure stenting of a patient respiratory system without a substantial direct flow from a flow generator of respiratory treatment apparatus to the patient during patient expiration.