A flowback tank cleaning system and method is described. A flowback tank includes a self-cleaning system. A flowback tank cleaning method may include moving solid debris collected at a bottom of a collection section of a flowback tank towards a lift auger using a cleaning auger or a conveyer belt extending along a length of the collection section, the bottom of the collection section including an angled trough, funneling solid debris towards the cleaning auger or conveyor belt by placing the cleaning auger or conveyor belt at a base of the angled trough, spraying fluid downward through a series of fluid outlets, removing the sand so moved by the cleaning auger or conveyer belt from the flowback tank using the lift auger, and removing the fluid from the flowback tank using a drain manifold below the cleaning auger or conveyer belt.

A substrate processing apparatus includes a substrate support unit, supporting a substrate, and an ultrasonic cleaning module disposed in a location lower than an upper surface of the substrate support unit. The ultrasonic cleaning module may include a receiving portion receiving a chemical, an opening portion in which at least a portion of an upper surface of the receiving portion is opened, and an ultrasonic vibration unit disposed to be directed toward the opening portion from the receiving portion, and may be configured in such a manner that a liquid surface of the chemical, rising by the ultrasonic vibration unit, touches the substrate through the opening portion.

Embodiments of megasonic cleaning chambers are provided herein. In some embodiments, a megasonic cleaning chamber includes: a chamber body defining an interior volume therein; a substrate support to support a substrate disposed in the interior volume; a supply tube comprising a transparent material configured to direct a cleaning fluid to the substrate support; a megasonic power generator coupled to the supply tube to provide megasonic power to the cleaning fluid; a megasonic transducer coupled to the megasonic power generator and the supply tube to create megasonic waves in the cleaning fluid and to form cavities in the cleaning fluid, wherein the megasonic transducer is configured to direct the megasonic waves and cavities toward the substrate support; and one or more sensors configured to generate a signal indicative of a property of the cavities in the cleaning fluid.

The present disclosure provides an ultrasonic system used for cleaning or other processing operations, the ultrasonic system including an ultrasonic device having a plurality of ultrasonic transducers coupled to the flexible body. The ultrasonic device may include one or more types of heating elements and may be configured as a tube, a belt, or otherwise configured depending upon the example. The ultrasonic system may further include a power supply coupled to the ultrasonic device and configured to apply a current to the plurality of ultrasonic transducers to remove contaminants from the one or more components, a fluid vessel configured to supply fluid in the form of liquid or gas or combinations thereof to the component(s) to flush the contaminants removed from the one or more components, and a waste vessel configured to collect the fluid supplied to the ultrasonic device from the fluid vessel.

A method of remediating a media asset comprising a magnetic tape includes preliminarily cleaning the media asset, treating the media asset, and finally cleaning the media asset. Treating the media asset includes baking the media asset, determining whether adjacent layers of the tape are stuck to each other, and re-baking the media asset. If adjacent layers of the tape are stuck to each other, the method includes submerging the magnetic tape in a cleaning bath for a predetermined period of time, unwinding the magnetic tape from a supply reel to a take-up reel at an unwind speed while drying the magnetic tape, and rewinding the magnetic tape onto the supply reel at a rewind speed before re-baking the media asset.

A recycling production line for horseshoe-fired-melting-furnace waste glass is provided, which includes a pre-flushing mechanism used for cleaning, a secondary cleaning mechanism and a drying mechanism. Two conveying mechanisms are mounted at a lower end of the pre-flushing mechanism and a lower end of the drying mechanism, respectively. The secondary cleaning mechanism is arranged between the two conveying mechanisms. An oscillating mechanism is arranged between the pre-flushing mechanism and the conveying mechanism. Through the cooperation of the pre-flushing mechanism and the oscillating mechanism, when glass cullet is flushed for the first time, the effective vibration force and the flushing force can be provided, the cleaning effect is guaranteed, water resources can be recycled, and energy resources are saved. The ultrasonic cleaning, and the drying that is performed at a drying temperature with temperature ranges are utilized, to improve the cleaning degree for later use.

A method for continuously cleaning a moving strip in a cleaning installation including a tank containing an aqueous solution, at least a roll immerged in the aqueous solution for guiding the strip into the tank, at least an ultrasound emitter a feed for feeding an aqueous solution inside the tank, a tank emptier for emptying the tank, an aqueous solution estimator for estimating the aqueous solution level in the tank, a distance calculator for calculating, for each ultrasound emitter, its distance to the aqueous solution level and a power controller for controlling the power of the at least one ultrasound emitter including the following steps, performed continuously: —estimating the aqueous solution level in the tank, —calculating for each ultrasound emitter its distance to the aqueous solution level, —comparing for each ultrasound emitter its distance to the aqueous solution level to a determined threshold.

An ultrasonic cleaning apparatus capable of cleaning large-sized objects includes: a casing having a bottom surface that forms a tilted surface to oppose the object to be cleaned and having an ultrasonic transducer provided at an inner lower surface; a cleaning liquid supply device configured to supply cleaning liquid to a casing bottom surface; and a flow-speed accelerator that ejects the cleaning liquid by accelerating the flow speed of the cleaning liquid from the cleaning liquid supply device. The casing is formed by a main body including an upper plate, a projected part attached to a lower part of the upper plate, an outer lateral face extended from the projected part in a downward direction, and the bottom surface connected integrally at a lower end part of the outer lateral face. The bottom surface is formed to be tilted at a prescribed angle with respect to a horizontal plane.

The present invention discloses a method for effectively cleaning vias, trenches or recessed areas on a substrate using an ultra/mega sonic device, comprising: applying liquid into a space between a substrate and an ultra/mega sonic device; setting an ultra/mega sonic power supply at frequency f.sub.1 and power P.sub.1 to drive said ultra/mega sonic device; after the ratio of total bubbles volume to volume inside vias, trenches or recessed areas on the substrate increasing to a first set value, setting said ultra/mega sonic power supply at frequency f.sub.2 and power P.sub.2 to drive said ultra/mega sonic device; after the ratio of total bubbles volume to volume inside the vias, trenches or recessed areas reducing to a second set value, setting said ultra/mega sonic power supply at frequency f.sub.1 and power P.sub.1 again; repeating above steps till the substrate being cleaned.

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.