Provided are an apparatus and a method for reaction for use in a co-precipitation reaction for preparing a catalyst or a cathode active material for a lithium secondary battery, which injects a raw material (a solution) at least between impellers according to the solution level in a vessel, thereby making a stirring speed uniform and, in particular, minimizing a concentration difference between solutions. The apparatus for the reaction may comprise: a reaction vessel; a stirring means provided inside the reaction vessel and having multistage impellers; and a raw material injecting means, comprising at least one injection nozzle connected to the reaction vessel, for injecting a raw material at least between impellers.

A single-pass flow-through dry chemical mixing trailer for use with a well has a trailer, a refillable liquid storage tank, a main liquid storage tank valve, a liquid storage tank inlet valve, an onboard power supply, a motor with a fuel supply, a transmission, a fluid circulation loop, a self-priming bidirectional flow alternating centrifuge pump, an automated mixer assembly, and a discharge tank. The refillable liquid storage tank prevents backflow to the self-priming bidirectional flow alternating centrifuge pump while flowing the homogenized slurry to the well and the dry chemicals introduced at the automated mixer are subjected to high shear forces, incorporating the dry chemicals into the liquid with increased dispersion and reduced agglomeration.

A multi-purpose accessory single, double level swivel platform plates is provided for consumable beverage containers and other usage such as keep liquid circulating for balance of taste, color, consistency of texture in beverages. The new invention's bottom portion mechanism unit is great for stress force cleaning applications such as on tiny foods and small parts. The main major focus is platform plates solutions to liquid beverages. The platforms single level, double level with swivel axle and nozzle are the main important factor for the container. This invention's container performs with physical hand pressure force exerted on its nozzle that's attached to the single or double swivel platforms counteract within its compression convolution internal cavity walls. The bottom accelerator portion device is designed for force stress Convergent flow through the nozzle. The nozzle produce conical and velocity conditions that work in conjunction within its upper part called the liquid volume hollow cylinder container. The new invention's nozzle, single, double swivel platform plates designed to vacuum lock suction liquid to produce jet plume convergent and divergent pressure within its nozzle. The (P, 0) and (T, 0)=[pressure and temperature upstream flow]. The nozzle uniquely qualifies as non-calibrated orifice flow, because the stress mechanism designed for its new invention's isn't supported by any engine power entity on the part. But only performs with physical hand pressure stress force on its convergent and divergent pressure of the nozzle. The platform plate's has a desired control feature called swivel axle. The swivel method is design to control divergent flow through its release holes into the container. The top liquid volume hollow cylinder container portion device will determine on the person's judgement for the amount of liquid fluid. The liquid volume has lines or markings for notifying by way of tolerable desired liquid level and by way of preventing no over spills out from the hollow cylinder container. The single, double level platform plate's build-in swivel axle part and nozzle and top liquid volume hollow cylinder container are unique parts. The pieces connect to form a container by threaded attachment to make one whole working part. The container's solitary design is to minimize results of layers of separation in beverages.

Systems for water treatment may include an evaporation unit, wherein the evaporation unit may comprise: a first blower; a spacer, wherein the spacer may be fluidly coupled to the first blower; wherein the evaporation unit may be configured to aerate and evaporate water; and a drying tunnel, wherein the drying tunnel may comprise: a second blower, wherein the second blower may be fluidly coupled to an end of the drying tunnel; a heater coupled to an exterior surface of the drying tunnel; nozzles disposed between the heater and the second blower; and a chamber configured to collect solids; wherein the drying tunnel may be configured to evaporate water.

The invention provides a device for enhancing liquid-liquid emulsification. The device includes a jet part and a mixing part connected to the jet part. The jet part includes a feed tee for feeding major and dispersed phases, wherein the feed tee includes a first port, a second port, and a third port. The first port is used for feeding the major phase, and the second port is equipped with an ejector for feeding the dispersed phase. The ejector consists of an ejector housing and an ejector inlet section, as well as a spiral structure, a flow-guided structure, and an ejector pin structure that are connected sequentially. The mixing part includes a mixer comprising a cylindrical mixer shell, a mixer inlet section, a mixer outlet section, as well as a spiral section, a cavity section, and a variable diameter section for enhancing emulsion breakup and dispersion. A method for enhancing liquid-liquid emulsification is also disclosed. The emulsion produced by the device and method of the invention is uniformly dispersed, has long stability, and the device has a compact structure and low energy consumption. It is particularly suitable for liquid-liquid emulsification processes in fields such as chemical industry, food, coatings, and cosmetics.

A water treatment system (1) for a reservoir (3) of water (5) including a mixing unit (2) located outside of the reservoir (3) and in an overall flow path of water from the reservoir (3) to and through the mixing unit (2) and back into the reservoir water (5). The mixing unit (2) is operable in three disinfectant modes that selectively add (a) chlorine, (b) ammonia, or (c) a blended mixture of chlorine and ammonia forming chloramines into the water returning to the reservoir (3). The mixing unit (2) also has hard and soft flush modes. In the hard flush mode, water (5) from the reservoir (3) is continually moved to flush through the mixing unit (2) and back to the reservoir (3). In the soft flush mode, the incoming hard water (5) from the reservoir (3) is softened to remove calcium and other minerals before passing through the mixing unit (2) and back to the reservoir (3) to reduce the undesirable build up of mineral deposits in the mixing unit (2).

Disclosed herein are a method for producing a miniaturized liposome on a large production scale, and an apparatus for producing a liposome which is to be used in the above-mentioned method. Provided is a method for producing a liposome, including a step of stirring a mixture containing an oil phase in which at least one lipid is dissolved in an organic solvent and a water phase in a first tank of an apparatus having the first tank and a circulation path, in which the ratio of the capacity of the circulation path to the total capacity of the tank and the circulation path is 0.4 or less and/or the time required for the mixture to return to the first tank after being discharged therefrom is within 2.0 minutes.

An example mobile drilling fluid plant includes a plurality of intermodal containers each exhibiting a length, a width, and a height compliant with universal shipping container dimensions and configurations dictated by the International Organization for Standardization, wherein the plurality of intermodal containers include a plurality of fluid storage containers and one or more fluid mixing containers, one or more pumps in fluid communication with the plurality of fluid storage containers and the one or more fluid mixing containers, and one or more flexible hoses fluidly coupled to the one or more pumps and placing the plurality of fluid storage containers in fluid communication with the one or more fluid mixing containers.

A bubble-generating apparatus comprises: a casing defining a casing bore extending longitudinally therethrough; and a diffuser located in the casing bore, the diffuser defining a diffuser bore extending longitudinally therethrough. The diffuser bore comprises a fluid-input region at or near a fluid-input end of the diffuser and a fluid-output region at or near a fluid-output end of the diffuser. A cross-sectional area of the diffuser bore in the fluid-input region is greater than the cross-sectional area of the diffuser bore in the fluid-output region. At least a portion of the diffuser is porous for permitting a flow of pressurized gas from a region of the casing bore located outside of the diffuser bore, through the porous portion of the diffuser and into the diffuser bore.

The embodiments herein disclose a method and apparatus for mixing sludge retained in a digester. A jet nozzle assembly for mixing contents of a vessel is used. The jet nozzle assembly having a central outlet pipe terminating at a jet nozzle, a low pressure nozzle assembly disposed concentrically about the central outlet pipe, the low pressure low pressure nozzle having a plurality of openings disposed circumferentially about the low pressure nozzle assembly. The plurality of openings are an axial distance from the outlet jet nozzle.