A humidification system has a tube configured to transport gases. The tube is configured to be soaked prior to use and has a bead to hold liquid. Heat applied to the bead causes the liquid to be released as vapour. Gases flowing through the tube are heated and humidified by the vapour.

A humidification system has a tube configured to transport gases. The tube is configured to be soaked prior to use and has a bead to hold liquid. Heat applied to the bead causes the liquid to be released as vapour. Gases flowing through the tube are heated and humidified by the vapour.

Systems, methods, and devices are disclosed for humidifying a breathing gas that reduces and/or eliminates the dangers and discomforts experienced by a patient. In one aspect, a system for humidifying gases includes a body, extending along a first axis from a first face to a second face, a first lumen at the first face, through which fluid enters the body, a second lumen at the first face through which fluid exits the body and a nonporous membrane located inside the body and extending from the first face to the second face wherein gas moving through the nonporous membrane is humidified by the fluid.

The invention relates to an inhaler component for forming a vapor/air mixture or/and condensation aerosol by evaporation of a liquid material and, if appropriate, condensation of the formed vapor, comprising: an electric heating element for evaporating a portion of the liquid material; a wick with a capillary structure, which wick forms a composite with the heating element and automatically supplies the heating element with the liquid material; a carrier plate, preferably a printed circuit board, which carries the composite and on which the heating element is electrically contacted; a capillary gap formed at least partially by the carrier plate and automatically supplying the composite with the liquid material, by means of an end portion of the wick extending into the capillary gap; a liquid container which contains the liquid material and from which the capillary gap draws the liquid material. In order to achieve a compact overall arrangement, it is proposed that the capillary gap at least partially covers the liquid container on the outside, in a view perpendicular to the carrier plate.

The invention relates to an inhaler component for forming a vapor/air mixture or/and condensation aerosol by evaporation of a liquid material (18) and, if appropriate, condensation of the formed vapor, comprising: an electric heating element for evaporating a portion of the liquid material (18); a wick with a capillary structure, which wick forms a composite (10) with the heating element and automatically supplies the heating element with the liquid material (18); a carrier plate (11), preferably a printed circuit board, which carries the composite (10) and on which the heating element is electrically contacted; a capillary gap (16) formed at least partially by the carrier plate (11) and automatically supplying the composite (10) with the liquid material (18), by means of an end portion of the wick extending into the capillary gap (16); a liquid container (19) which contains the liquid material (18) and from which the capillary gap (16) draws the liquid material (18). In order to achieve a compact overall arrangement, it is proposed that the capillary gap (16) at least partially covers the liquid container (19) on the outside, in a view perpendicular to the carrier plate (11).

The present invention relates to a humidifier for humidifying medical gases, comprising a humidification module including a control unit, wherein the humidification module is adapted for receiving a humidification chamber. Furthermore, the humidification module is further adapted to sense and/or receive information upon connection of the humidification chamber and/or additional equipment such as hoses, power supply pack.

An apparatus for treating a respiratory disorder in a patient, includes a respiratory pressure therapy device that generates a flow of air at positive pressure for treating the respiratory disorder. An air circuit transports the flow of air generated by the respiratory pressure therapy device to a patient interface. A nebuliser module is located at or adjacent to a proximal end of the air circuit to nebulise a liquid to form a nebula of the liquid. The nebula is admitted into the flow of air generated by the respiratory pressure therapy device. A vaporiser is located at the distal end of the air circuit to receive and vaporise the nebula to form a humidified flow of air.

A humidification device (200A) includes a reservoir (216), a vaporizer (250), a water supply passage (230), a gas introduction passage (240), a gas introduction source (260), and a controller. The reservoir (216) stores water. The vaporizer (250) vaporizes the water supplied to the vaporizer (250). The water supply passage (230) is connected to the reservoir (216) and the vaporizer (250) and filled with the water flowing from the reservoir (216). The gas introduction passage (240) is connected to an intermediate position of the water supply passage (230). The gas introduction source (260) introduces gas into the water supply passage (230) through the gas introduction passage (240) so as to push out, by using pressure of the introduced gas, toward the vaporizer (250) the water with which the water supply passage (230) is filled. The controller controls operation of the gas introduction source (260).

Systems, methods, and devices for humidifying a breathing gas using a vapor transfer unit are presented. The method includes providing a first vapor transfer unit having a gas passage and a liquid passage, delivering a liquid to the liquid passage, delivering a gas to the gas passage, humidifying the gas by delivering vapor from the liquid in the liquid passage to the gas in the gas passage, exiting the humidified gas outside the vapor transfer unit at first relative humidity and at a high gas flow rate, and reducing the gas flow rate through the first vapor transfer unit to less than a low gas flow rate, while preventing the relative humidity from exceeding the first relative humidity by more than an acceptable margin.