The present disclosure relates to a system and method for treating wastewater, the method comprising the steps of: providing a vessel for receiving wastewater and a gas, wherein the gas comprises one or more constituent gas components; directing the wastewater and a first gas component of the gas to the vessel; reducing the temperature of the contents of the vessel from a first temperature to a second temperature to facilitate the formation of clathrate hydrates comprising the wastewater and the first gas component; increasing the temperature of the contents of the vessel with respect to the second temperature to facilitate melting of the clathrate hydrates; and removing clean water and/or the first gas component from the vessel.

The present invention relates to a mixing machine configured to receive a receiving device in order to form a manufacturing apparatus, the mixing machine comprising: a support defining a receiving housing, able to receive a receiving device, the receiving device being configured to receive first and second capsules containing respectively a first formulation and a second formulation, the two capsules being fluidly linked to each other, an actuation system, movable inside the receiving housing to exert a pressure force on the receiving device and/or on the first and/or the second capsule(s), a retention mechanism, movable relative to the support and configured: in an insertion position, to authorize the insertion and the withdrawal of the receiving device into/from the receiving housing, and in a retention position, to block the withdrawal of the receiving device from the receiving housing.

A receptacle comprises opposed members, a plurality of chambers having perimeter walls defined by seals formed between the opposed members and portals interconnecting the chambers, and a rigid frame supporting the opposed members at their peripheral edges. The frame comprises a front frame portion and a rear frame portion, and the peripheral edges of the opposed members are retained between the front and rear frame portions. An inlet port extends between the front and rear frame portions and is in fluid communication with one of the chambers.

A method of processing a sample in a receptacle comprising a plurality of chambers. Each of the chambers is connected to at least one other chamber by a portal and at least a first one of the chambers is formed of a flexible material. The method includes the steps of causing gas bubbles contained in the first chamber to accumulate in a portion of the first chamber, applying a compressive external force to the first chamber to cause some or all of the liquid contents of the first chamber to flow into an interconnected second chamber through a portal connecting the first and second chambers; and preventing the gas bubbles accumulated in a portion of the first chamber from flowing through the portal into the second chamber

The disclosure relates to devices and methods for analyzing particles in a sample. In various embodiments, the present disclosure provides devices and methods for cytometry and additional analysis. In various embodiments, the present disclosure provides a cartridge device and a reader instrument device, wherein the reader instrument device receives, operates, and/or actuates the cartridge device. In various embodiments, the present disclosure provides a method of using a device as disclosed herein for analyzing particles in a sample.

Provided are a device for generating an ozone-containing UFB liquid and a method for generating the ozone-containing UFB liquid, which enable the generation of the ozone-containing UFB liquid that can be stored long-term at a high concentration. To this end, an ultrafine bubble liquid containing ultrafine bubbles is generated by applying energy to a liquid and ejecting the liquid from an ejecting port having a small diameter, and the generated ultrafine bubble liquid is irradiated with ultraviolet ray.

A method and system are used to enhance a marker material to include a plurality of air bubbles. The method of manufacturing a marker includes enhancing a marker material to include a plurality of air bubbles using at least a first EFD and a second EFD. The method may include cycling repeatedly through a transfer process between a first container and a second container. A system for enhancing a marker material includes a transfer apparatus configured to receive a marker material and a selected amount of air. The system comprises a first EFD coupled to a first end of the transfer apparatus and a second EFD coupled to a second end of the transfer apparatus.

A receiving device for forming a mixing machine, when the receiving device is inserted into a manufacturing apparatus, includes: a first receiving location configured to receive a first capsule containing a first formulation, a second receiving location configured to receive a second capsule containing a second formulation, the two capsules configured to be fluidly linked to each other, a first actuation face of the receiving device, authorizing a transfer of a pressure force on the first capsule, the first actuation face having a first protective shell, a second actuation face of the receiving device, opposite to the first face, authorizing a transfer of a pressure force on the second capsule, the second actuation face having a second protective shell, and a flap opening outwardly of the receiving device and extending between the two receiving locations, to authorize insertion of the capsules separately and extraction of the capsules jointly.

Described here are apparatuses and methods for producing a composition comprising nano-bubbles dispersed in a liquid carrier. One such method includes flowing a liquid carrier from an inlet through at least two channels each including a triboelectric material, including flowing the liquid carrier such that a Reynolds number of the flow of the liquid carrier through the at least two channels is less than 3000. Flowing the liquid carrier through the at least two channels produces vibrational energy that causes: (i) the liquid carrier to contact the triboelectric material such that an electric charge is generated in the triboelectric material; and (ii) the liquid carrier to separate from the triboelectric material such that the electric charge is discharged to the liquid carrier to form nano-bubbles dispersed in the liquid carrier.

Reagents used in automatic analysis devices, which analyze components in a biological sample by mixing and reacting the biological sample with a reagent, include liquid reagents and freeze-dried reagents, and freeze-dried reagents must be dissolved by a solvent. Fragments of freeze-dried reagent attach to the upper section, such as the wall surfaces and around the lid, of a reagent container containing the freeze-dried reagent. In order to dissolve these fragments, the reagent bottle must be subjected to inversion mixing, in which a reagent bottle is rotated while being turned sideways and upside-down. However, when doing so, liquid is liable to leak from the opening part of the reagent container. Provided is an automatic analysis device characterized by: comprising a reagent container, a reagent disk for holding the reagent container, a dispensing mechanism for dispensing a solution into the reagent container, an inversion mixing mechanism for subjecting the reagent container to inversion mixing, and a control unit for controlling the dispensing mechanism and the inversion mixing mechanism; the inversion mixing mechanism having a rotating mechanism for rotating the reagent container and a tilting mechanism for tilting a rotating shaft of the reagent container; the reagent container having a lid which can be pierced; the lid having a tubular mechanism having an opening part formed at the tip end and extending inside the reagent container; and the control unit controlling the dispensing conditions of the dispensing mechanism such that the position of the opening part formed at the tip end of the tubular mechanism is further up than the liquid surface of the solution contained in the reagent container, regardless of whether the reagent container is being held upright, upside-down, or sideways by the inversion mixing mechanism.