An oxygen nanobubble system may include a liquid source for liquid to be treated with oxygen nanobubbles. The system may also include a field portable oxygen nanobubble device including a portable housing, an air compressor carried by the portable housing and configured to generate compressed air, an air dryer carried by the portable housing and coupled downstream from the air compressor, an oxygen concentrator carried by the portable housing and coupled downstream from the air dryer, and a liquid pump carried by the portable housing and configured to pump liquid from the liquid source. The field portable oxygen nanobubble device may also include an oxygen nanobubble generator carried by the portable housing and coupled downstream from the liquid pump and to the oxygen concentrator to generate oxygen nanobubbles within the liquid.

A surface water treatment system may include a surface water source and an oxygen nanobubble device. The oxygen nanobubble device may include an air compressor configured to generate compressed air, an air dryer coupled downstream from the air compressor, and an oxygen concentrator coupled downstream from the air dryer. The oxygen nanobubble device may also include a recirculating surface water pump coupled to the surface water source. The oxygen nanobubble device may also include an oxygen nanobubble generator coupled downstream from the recirculating surface water pump and coupled to the oxygen concentrator to generate oxygen nanobubbles within the surface water.

The use of polyferric sulphate (PFS) or ferric sulphate (FS); and sulphuric acid (SA); in combination to treat liquid animal effluent and/or sludge (i.e., a combination treatment), to reduce methane emissions from liquid animal effluent and/or sludge (i.e., a combination treatment), compared to untreated liquid animal effluent and/or sludge.

A liquid polymer dosing and mixing chamber and pump having a pump housing, a mixing reactor, a spacing cup, an actuator, a drive shaft, a drive shaft coupling unit, and a progressive cavity pump adapted to create doses of a first substance and to mix it with one or more substances introduced into the mixing reactor via one or more inlets.

Apparatus and associated methods relate to a passive automatic injector reactor system (PAIRS). In an illustrative example, an energy storage enclosure may contain energy storage modules (e.g., batteries) releasing target gas(es) (e.g., toxic, flammable). The PAIRS may, for example, include an injector in fluid communication with the enclosure. The injector may, for example, passively direct target gases released from the enclosure to a mixing area where supplemental gas(es) are entrained with the target gases to create a target gas air mixture that is directed to a reactor. The reactor may, for example, utilize one more chemical, physical, and/or physiochemical processes to convert the target air gas mixture into a processed gas before release. Various embodiments may advantageously prevent fire, explosion, and/or the release of toxic gas from batteries.

The present disclosure relates to a device and method for continuous mixing of a solid drag reducer. The device for continuous mixing of a solid drag reducer comprises a raw material storage device (1), a pneumatic raw material delivery device (2), a power device (3), a flow testing device (4) and a dissolving device (5). The method for continuous mixing of a solid drag reducer uses the device for continuous mixing of a solid drag reducer, which can realize continuous mixing of the solid drag reducer during large-scale volume fracturing.

An apparatus, includes: a first raw material supply unit 110 including a filter housing 111, a supply fan 112, a flow regulator 113, an electronic valve 114, and an air supply line 115, wherein the supply fan 112 is operated to suck in external air, in the process, the HEPA filter (not shown) mounted inside the filter housing 112 filters fine dust and adjusts the air supply flow rate from the flow regulator 113 to the appropriate flow rate and supplies through the supply line 115 to the ion generator 200; a second raw material supply unit 120 including a pressure regulator 122, a flow regulator 123, an electronic valve 124, and an air supply line 125.

A sludge and polymer conditioning system that includes a progressive cavity pump, a mixing reactor, a drive shaft, an actuator or motor, a first reaction chamber, a reducer connector, a check valve, a spray nozzle, and a second reaction chamber.

A solution management system (1) for bioprocessing, wherein each flow path formed between solution inlets (2) and solution outlets (9) of the system comprises one or more bend sections having an inner cross-sectional area and/or an inner cross-sectional geometry and/or a centre line radius varying along the length of the bend section. Various embodiments of the solution management system (1) provide for improved laminar fluid flow with a reduced pressure drop between the solution inlets (2) and solution outlets (9) therein.

A system for processing a biological sample can include a droplet generation assembly comprising a plurality of first reservoirs configured to contain an aqueous sample and a plurality of second reservoirs configured to contain a carrier fluid immiscible with the aqueous sample. The plurality of first reservoirs and the plurality of second reservoirs can be arranged to be in respective flow communication in pairs of reservoirs comprising a first reservoir of the plurality of first reservoirs and a second reservoir of the plurality of second reservoirs constituting a plurality of pairs of reservoirs. The droplet generation assembly can further include a flow control system configured to control a pressure in the plurality of pairs of reservoirs so as to generate a flow of a series of volumes of the aqueous sample separated by the carrier fluid. The system can further include a thermocycling system.