The present invention comprises a body which houses the waterproof vacuum pump, rechargeable battery and the user display interface and a reservoir to hold the aspirated content. Attached to the body of the invention is an extended removable suction head. This portion of the device is used to navigate and aspirate the mouth from unwanted content such as but not limited to tonsil stones, debris and liquids.

The present disclosure discloses a device for automatically collecting snot, which comprises a suction nozzle, a collecting cup, a cup holder and a shell component which are detachably connected in sequence, wherein the shell component is a hollow cavity. The present disclosure generates negative pressure suction through the air pump, and then the suction air enters the inner collecting cup through the air suction pipe, the cup holder air inlet, the air inlet channel and the micropore in sequence. Finally, the suction sucks the snot in the nose of a user into the inner collecting cup through the suction nozzle, effectively solving the problem of snot reflux.

A nasal aspirator suction bin assembly comprises a suction bin base, which has a first connecting end connected with a host and a second connecting end connected with a suction bin cover; after the suction bin base is connected with the suction bin cover, a cavity is formed therein; the middle of the suction bin base is provided with an outlet tube, which runs through the suction bin base and extends into the cavity; the upper end of the suction bin cover is provided with a suction tube, which runs through the suction bin cover and extends into the cavity; a bracket is arranged in the cavity, and the bracket comprises a bracket tube which can be inserted on the outlet tube and a baffle arranged at the other free end of the bracket tube, and at least one air hole is arranged on the bracket tube to keep the suction tube and the outlet tube in communication all the time; the cavity is used to store the inhaled nasal fluid. Because of the umbrella-shaped bracket, the nasal fluid cannot touch the position of the air hole during normal use and small-angle inclined use, so the nasal fluid cannot enter the host and cause pollution.

A nasal mucus suction device includes an air pump and a head structure. The air pump has an intake tube and an outlet tube. The head structure is coupled to the intake tube and the outlet tube of the air pump, and defines a channel between a nasal mucus suction inlet and a gas outlet. The channel includes a first channel section in communication with the nasal mucus suction inlet, and a second channel section in communication with the gas outlet. The first channel section includes at least one mucus storage cavity, the second channel section is in communication with the intake tube and the outlet tube of the air pump. The first channel section has a maximized path length, and includes an anti-backflow channel structure. The second channel section includes a noise reduction space.

The present disclosure illustrates a nasal aspirator with a lighting function. The nasal aspirator includes a main body, a power supply unit, a sucking unit, air extracting unit, and a lighting unit. The power supply unit is disposed in the main body. The sucking unit is coupled with and extended out of the main body and configured to insert into a nasal cavity. The air extracting unit is disposed in the main body and electrically coupled with the power supply unit, and configured to enable the sucking unit to generate suction. The lighting unit is disposed in the sucking unit, and the power supply unit is configured to drive the air extracting unit and the lighting unit.

A portable urinal device includes a base forming a liquid receptacle. Tubing extends from the base to a head member which can be positioned onto genitalia for urination. Suction is provided via a pump or vacuum device to suction urine from the head into the base receptacle.

Quantifying blood loss with a medical waste collection system including a receiver with which a manifold is removably coupled. The manifold and/or the medical waste collection system is coupled with a fluid characterization module having a sensor assembly to detect a characteristic indicative of a blood concentration within fluid. The sensor assembly may include emitters, and sensors to detect light transmitted and scattered by the fluid in a suction path or a detection window. A first emitter may be a visible-light LED, and a second emitter an infrared LED. A fluid director may provide a tortuous path within the manifold and facilitate separation of gas and liquid within the fluid. Quantifying the blood loss volume may include determining the blood concentration within the fluid, and determining a volume of the collected fluid. Gain of the sensors may be adjusted based on the transmissivity of the collected fluid.

A visual beauty instrument includes a control module, an image acquisition module, a suction control module, a fill light module, a suction nozzle assembly and a mobile terminal. The image acquisition module collects the image signal of the suction area and feeds back the image signal to the control module. The control module analyzes the image signal and controls the suction control module and the fill light module. The suction control module sucks up the acne and blackheads on the skin surface by the suction nozzle assembly. The fill light module improves the recognition of acne and blackheads. The invention can observe the distribution and size of blackheads and acne in the inner layer of the skin and compare the number of blackheads and acne before and after suction, ensuring thorough cleaning, improving removal efficiency and preventing skin damage caused by excessive suction.

An ear and nose secretion extractor apparatus for removing mucus and cerumen includes a headband configured to be worn on a crown of a user's head. A housing is coupled to the headband and defines a housing cavity. A pump and a battery are coupled to the housing within the housing cavity. A nasal arm is coupled to the housing. A pair of nasal collection chambers is coupled to the nasal arm. A pair of nasal nozzles is coupled to the pair of nasal collection chambers. A pair of aural arms is coupled to the headband. A pair of aural collection chambers is coupled to the pair of aural arms. The pair of aural collection chambers is in fluid communication with the pump. The pump creates suction through the nasal nozzles. The pair of aural nozzles is configured to be inserted into a user's ears.

A motorized medical suction pump has a pump assembly for generating an underpressure, a pump assembly carrier for supporting the pump assembly, and a seat for receiving an energy accumulator. The pump assembly arranged in the pump assembly carrier defines a first longitudinal axis, and the seat defines a second longitudinal axis. The pump assembly carrier forms the seat. The second longitudinal axis extends at an angle to the first longitudinal axis. This suction pump is small and compact and has good sound damping.