An automatic pet feeder includes a food container, a feeder body, and a bottom shell in sequence from top to bottom. A food-container bottom shell in communication with the food container is arranged at a bottom of the food container, and a bottom of the food-container bottom shell is a food supply passage having a gradually narrowing opening. A food releasing assembly is arranged on a side of the food supply passage, and a sliding passage for reciprocating movement of the food releasing assembly is arranged on a sidewall of the food-container bottom shell. A feeder main shell is arranged below the food supply passage, and a food exit assembly is arranged inside the feeder main shell. The food exit assembly includes a food pushing member matching with a food outlet and configured to move in a reciprocating manner below the food supply passage.

An automatic pet feeder includes a food container, a feeder body, and a bottom shell in sequence from top to bottom. A food-container bottom shell in communication with the food container is arranged at a bottom of the food container, and a bottom of the food-container bottom shell is a food supply passage having a gradually narrowing opening. A food releasing assembly is arranged on a side of the food supply passage, and a sliding passage for reciprocating movement of the food releasing assembly is arranged on a sidewall of the food-container bottom shell. A feeder main shell is arranged below the food supply passage, and a food exit assembly is arranged inside the feeder main shell. The food exit assembly includes a food pushing member matching with a food outlet and configured to move in a reciprocating manner below the food supply passage.

Provided is a light irradiation device capable of safely detecting liquid leakage in the occurrence of the liquid leakage. A light irradiation device includes a light-emitting element, a cylindrical light source supporter having an outer wall surface on which the light-emitting element is disposed, a flow groove formed on the outer wall surface in an axial direction of the light source supporter, a reservoir that is communicated to the flow groove at a first end of the light source supporter in the axial direction and that is configured to allow liquid to be stored, and a detector configured to detect the liquid stored in the reservoir. The first end of the light source supporter is located at a position downward in the vertical direction relative to a second end of the light source supporter, the reservoir being disposed at the first end in the axial direction thereof.

The invention relates to a patient interface comprising a plenum chamber, a seal-forming structure, and a positioning and stabilizing structure, as well as the method of operating the patient interface. The patient's interface is configured to leave a patient's mouth uncovered or if the seal-forming structure is configured to seal around a patient's nose and mouth, the patient interface is configured to allow the patient to breath from the ambient in an absence of the flow of pressurized. The positioning and stabilizing structure includes headgear, and the seal-forming structure and at least a portion of the headgear is formed from a one piece construction of textile material. In another embodiment, the seal-forming structure and/or the positioning and stabilizing structure includes an adaptive portion that adjusts based on usage conditions. In another embodiment, the positioning and stabilizing structure, the seal-forming structure and/or the plenum chamber includes and/or is formed of a textile material, and the textile material includes at least one magnetic thread constructed of magnetic material to provide a magnetic interaction between a first part of the patient interface and a second part of the patient interface. In another embodiment, a stiffener is coupled to the plenum chamber, the seal-forming structure, and/or the positioning and stabilizing structure. In another embodiment, at least one of the plenum chamber and the seal-forming structure includes a textile material; and wherein the textile material includes a surface structure that limits adhesion of debris. A UV cleaning receptacle of the patient interface is also disclosed.

A sterilization apparatus for sterilizing a respiratory mask is described. The sterilization apparatus comprises a sterilization chamber, an articulating mask support disposed inside the sterilization chamber, a bi-directional fan system disposed inside the sterilization chamber and configured to move air through an air passage to simulate human breathing, and a sterilization agent generator coupled to the sterilization chamber. The bi-directional fan system pumps air that includes the sterilization agent back and forth through the oxygen mask via the air passage, to mimic normal breathing of an individual using the mask.

A sterilization apparatus for sterilizing a respiratory mask is described. The sterilization apparatus comprises a sterilization chamber, an articulating mask support disposed inside the sterilization chamber, a bi-directional fan system disposed inside the sterilization chamber and configured to move air through an air passage to simulate human breathing, and a sterilization agent generator coupled to the sterilization chamber. The bi-directional fan system pumps air that includes the sterilization agent back and forth through the oxygen mask via the air passage, to mimic normal breathing of an individual using the mask.

Disclosed is a self-sanitizing enclosure for installation onto a table-top. The self-sanitizing enclosure includes a UVC light source, where the UVC radiation emitted from the UVC light source is configured to sterilize components that are stored within the self-sanitizing enclosure.

Disclosed is a self-sanitizing enclosure for installation onto a table-top. The self-sanitizing enclosure includes a UVC light source, where the UVC radiation emitted from the UVC light source is configured to sterilize components that are stored within the self-sanitizing enclosure.

Systems and methods for cleaning and maintaining artificial airways sized for insertion within pediatric or neonatal patients (e.g., external diameters of less than 5 mm) are disclosed. The system includes a multi-port ventilator manifold configured to couple to a ventilation source, thereby forming a ventilator circuit with the patient. The manifold includes an occluder configured to advantageously reduce an amount of dead space in the manifold so as to prevent less of positive end expiratory pressure of the ventilator circuit and reduce the likelihood of broncho-pulmonary dysplasia of the patient, or even premature death.

Systems and methods for cleaning and maintaining artificial airways sized for insertion within pediatric or neonatal patients (e.g., external diameters of less than 5 mm) are disclosed. The system includes a multi-port ventilator manifold configured to couple to a ventilation source, thereby forming a ventilator circuit with the patient. The manifold includes an occluder configured to advantageously reduce an amount of dead space in the manifold so as to prevent less of positive end expiratory pressure of the ventilator circuit and reduce the likelihood of broncho-pulmonary dysplasia of the patient, or even premature death.