The present disclosure provides an electronic cigarette automatic cleaning apparatus includes a main body having an accommodating space, a cleaning tub provided in an accommodating space of the main body and storing a cleaning material for cleaning an electronic cigarette device, a cover coupled to the cleaning tub and having a through hole through which a cleaning portion of the electronic cigarette device is immersed in the cleaning material, and an ultrasound generation portion provided in the main body and configured to emit ultrasonic waves to the cleaning material to separate a foreign material from the electronic cigarette device.

A dosing apparatus for dosing a powder product inside containers includes a hopper provided with an inner cavity for containing the product, a lower portion provided with a supply duct with a terminal aperture for the outflow of the product, a metering screw rotating inside the supply duct and a washing manifold provided with an inlet opening and containing at least a sonotrode. In a cleaning configuration of the dosing apparatus, the washing manifold is connected to the hopper coupling the inlet opening to the supply duct, so as to receive and contain a washing liquid introduced in the hopper. The sonotrode is activated to produce alternate pressure waves capable of generating in the washing liquid air bubbles adapted to propagate towards the inner cavity through the supply duct, and to implode thus creating shock waves.

A cleaning system and method uses a tank holding a fluid detergent and an equipment assembly formed from a plurality of discrete components joined together. One or more ultrasound transducers remove one or more deposits on the equipment assembly by generating and propagating high frequency ultrasound waves into the fluid detergent while the equipment assembly is in contact with the fluid detergent.

The group of inventions relates to the oil-and-gas extraction industry, in particular to equipment for removing deposits of asphaltenes, resins, paraffins, hydrates, calcium salts, etc. from tubing strings of oil and gas wells without extracting said tubing strings from the wells. This instrument can also be used for cleaning water-extracting wells and other wells. The internal surface of a tubing string is cleaned by a combined action (ultrasonic, mechanical, heat) on contaminants. Owing to the fact that operation of a well does not stop, dirt atomized by the combined action is raised to the surface and removed from the well by a stream of fluid. A system for ultrasonic cleaning of a tubing string consists of an ultrasonic generator and a downhole ultrasonic scraper, which comprises a converter converting electrical vibrations into mechanical vibrations, which is placed into a protective casing and is connected to a vibration transformer, which boosts the amplitude of vibrations of ultrasonic transducers. The use of the claimed group of inventions makes it possible to increase the efficiency and economy of an operation for cleaning a tubing string.

An additively manufactured component with an internal passage; and a multiple of ultrasonic horns additively manufactured within the internal passage. A method of removing conglomerated powder from an internal passage of an additively manufacturing a component, including ultrasonically exciting at least one of a multiple of the ultrasonic horns within an internal passage of an additively manufactured component

The application provides a cleaning device for residue in a washing machine, comprising a work table, a cleaning tank, an ultrasonic device and a placing basket. The work table comprises a bottom and a side; the cleaning tank is installed in the work table, and a heating rod is installed in the cleaning tank; the ultrasonic device is installed at the outer wall of the cleaning tank; and a mesh is defined in a side wall of the placing basket which is able to enter inside of the cleaning tank through an opening.

The firearm barrel cleaning system selectively cycles a stream of ultrasonic cleaning fluid through the barrel of a firearm, and further selectively ultrasonically induces cavitation within the cleaning fluid in the barrel for ultrasonic cleaning. The firearm barrel cleaning system includes a receiver assembly having a first end adapted for receiving the stream of cleaning fluid and a second end is adapted for insertion into the firearm receiver and sealing against a first end of the barrel to eject the stream of cleaning fluid into the barrel. A cap structure, having an outlet hose connector is clamped over the muzzle end of the barrel of the firearm. A pump selectively circulates the cleaning fluid through the receiver assembly, the barrel and out through the cap structure. An ultrasonic transducer is mounted on the receiver assembly for selectively inducing cavitation in the cleaning fluid.

A deposition system is provided capable of cleaning itself by removing a target material deposited on a surface of a collimator. The deposition system in accordance with the present disclosure includes a substrate process chamber. The deposition includes a substrate pedestal in the substrate process chamber, the substrate pedestal configured to support a substrate, a target enclosing the substrate process chamber, and a collimator having a plurality of hollow structures disposed between the target and the substrate, a vibration generating unit, and cleaning gas outlet.

A method for cleaning firearm suppressors comprising: providing a used suppressor having an internal cavity with a fouling material deposited on a surface of the internal cavity; providing a cleaning solution; providing an ultra-sonic probe; introducing the cleaning solution into the internal cavity of the used suppressor; contacting at least part of the ultra-sonic probe with the cleaning solution that is introduced inside the internal cavity of the used suppressor; operating the ultra-sonic probe; removing at least part of the fouling material from the surface of the internal cavity of the used suppressor; and, draining the cleaning solution from the used suppressor.

Disclosed is systems and methods for cleaning devices holding fluid such as heat exchanges. The cleaning is performed by using a system such as a transducer assembly including a mechanical wave generator and a waveguide including a cavity. The system is capable of operating at its fundamental resonance frequency even when connected to an outer surface of the device to be cleaned.