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.

Provided is a device for continuously decomposing a rare earth concentrate ore. The device includes a body, a bidirectional propeller and a driving assembly. The body has a material inlet, two liquid inlets and two exhaust gas outlets disposed at the top of the body, two material outlets disposed at the bottom of the body and a heat preservation chamber provided inside a side wall of the body. The bidirectional propeller is provided in the body and extends along a length direction of the body. The driving assembly is connected to the rotating shaft.

Provided is a carbon dioxide fluidity control device comprising, a sample preparation tank, a high-pressure stirring unit, a reciprocating plunger pump and a booster pump, wherein the stirring unit comprises one or more high-pressure stirring tanks, each provided with an atomizing spray probe and a piston, wherein a discharge port of the sample preparation tank is connected to the atomizing spray probe via a plunger pump, which is connected to the piston to push the piston to reciprocate; the booster pump is connected to the high-pressure stirring tanks to provide supercritical carbon dioxide to the high-pressure stirring tank; and a discharge port of the high-pressure stirring tanks is connected to an oilfield well group. Provided is a carbon dioxide fluidity control method using the device, comprising mixing surfactants and nanoparticles with heated carbon dioxide, and injecting a microemulsion of supercritical carbon dioxide and nano-silicon dioxide into an oilfield well group.

A brine maker including a hopper having an open upper end and an open lower end with the hopper being configured to receive salt therein. A solids screen is positioned at the lower end of the hopper. A receiving tank having an open upper end is positioned below the solids screen. An overflow tube is positioned in the hopper and has an upper end positioned below the upper end of the hopper. When the level of salt brine reaches the upper end of the overflow tube, the salt brine will overflow into the overflow tube and will pass downward therethrough the solids screen and into the receiving tank. The invention includes a second embodiment wherein an overflow panel with an upper end is positioned in the hopper thereby creating a passageway into which brine overflow may pass thereinto and pass through the solids screen into the receiving tank.

A brine maker including a hopper having upper and lower ends with a receiving tank positioned below the hopper. The forward end of the receiving tank has an opening formed therein. An elbow fitting is positioned in the opening in the forward end of the receiving tank and is welded to the forward end of the receiving tank. The elbow fitting includes a vertically disposed hollow upper portion which is positioned in the receiving tank and a horizontally disposed hollow lower portion which is positioned in the opening in the forward end of the receiving tank. The horizontally disposed hollow lower portion of the elbow fitting is fluidly connected to a pump. A shield is secured to the inner side of the forward end of the receiving tank above the upper end of the vertically disposed hollow upper portion of the elbow fitting.

The present application is directed towards systems for adding components to materials being fluidized in a vibratory mixer by use of atomizers or sprayers. A mechanical system can fluidizes, mix, coat, dry, combine, or segregate materials. The system may comprise a vibratory mixer, mixing vessel containing a first material and a sprayer to introduce a second material. The vibratory mixer may generate a fluidized bed of a first material and the sprayer, coupled to the mixing vessel, may introduce a second material onto the fluidized bed to mix the materials in a uniform and even fashion.

An automated system for automatically mixing and verifying paint is described. The system may include a kiosk configured to automatically add a paint of a second color to a paint container holding a first color of paint so as to produce a requested third color of paint. The system may further verify that the mixed paint color is the requested paint color using a laser to perform verification.

A brine maker including a hopper having an open upper end and an open lower end with the hopper being configured to receive salt therein. A solids screen is positioned at the lower end of the hopper. A receiving tank having an open upper end is positioned below the solids screen. An overflow tube is positioned in the hopper and has an upper end positioned below the upper end of the hopper. When the level of salt brine reaches the upper end of the overflow tube, the salt brine will overflow into the overflow tube and will pass downward therethrough the solids screen and into the receiving tank. The invention includes a second embodiment wherein an overflow panel with an upper end is positioned in the hopper thereby creating a passageway into which brine overflow may pass thereinto and pass through the solids screen into the receiving tank.

A mixing apparatus for mixing powder and liquid, includes: an apparatus main body having an internal space; a cylindrical member arranged in the internal space with one end facing upward and the other end facing downward, the one end and the other end being opened; a powder dispersing portion arranged above the apparatus main body, the powder dispersing portion dispersing the powder into a space of the cylindrical member; a liquid spraying portion arranged in a vicinity of the powder dispersing portion, the liquid spraying portion spraying the liquid into a space of the cylindrical member; a collection portion arranged below the apparatus main body, the collection portion collecting a mixed powder consisting of the powder dispersed by the powder dispersing portion and the liquid sprayed by the liquid spraying portion; a filter arranged around the cylindrical member in the internal space; and a discharge port discharging air in the internal space through the filter.

A sewage system component spray assembly is attached at a predetermined height above pumps in the interior of the component and has at least one nozzle for spraying liquid downwardly and generally tangential to a center of the sewage system component. Operation of the nozzle causes the liquid to disperse floating material on the sewage surface and creating a rotational flow around the center to direct such material to the pumps. The source of the sprayed liquid may be internal to the sewage system component.