Some variations provide a system for producing a functionalized powder, comprising: an agitated pressure vessel; first particles and second particles contained within the agitated pressure vessel; a fluid contained within the agitated pressure vessel; an exhaust line for releasing the fluid from the agitated pressure vessel; and a means for recovering a functionalized powder containing the second particles disposed onto surfaces of the first particles. A preferred fluid is carbon dioxide in liquefied or supercritical form. The carbon dioxide may be initially loaded into the pressure vessel as solid carbon dioxide. The pressure vessel may be batch or continuous and is operated under reaction conditions to functionalize the first particles with the second particles, thereby producing a functionalized powder, such as nanofunctionalized metal particles in which nanoparticles act as grain refiners for a component ultimately produced from the nanofunctionalized metal particles. Methods for making the functionalized powder are also disclosed.

A polymer dispersion system for use in a hydraulic fracturing operation is disclosed. The system comprises (a) a tank assembly comprising an ingress, an egress, and an interior volume for collecting mother solution; (b) a first transfer pump coupled with the egress of the tank assembly: and (c) a second transfer pump coupled with the egress of the tank assembly. The first transfer pump is configured for coupling to a missile unit and a blender unit downstream thereof, but in fluid communication with only one of such units at any given time when coupled. A method of operating said polymer dispersion system is also disclosed.

A mixing apparatus is configured to efficiently input noodles coated with an additive to a receiving tray, with no need to perform weighing again after the noodles are input to the receiving tray. The mixing apparatus includes at least two hoppers that each house falling noodles and that allows the noodles to fall through rotation of the hoppers. A supply device supplies a sauce to the noodles in the hoppers, and the two hoppers are spaced from one another in the falling direction.

A viscous material stirring apparatus includes a stirring member that rotates about a rotation axis and has a tip radially separated from the rotation axis, a rotary actuator that rotates the stirring member about the rotation axis, a moving mechanism that moves the stirring member, and a control device. The control device drives the moving mechanism to immerse the tip of the stirring member into an applied viscous material, drives the rotary actuator to rotate the stirring member around the rotation axis, and drives the moving mechanism to move the stirring member along a coating direction of the viscous material with the tip of the stirring member immersed in the viscous material.

A mixing bowl tilting assembly includes a support frame that can be positioned on a support surface. A pair of uprights is each pivotally coupled to the support frame. Each of the uprights is positionable in a deployed position having each of the uprights being vertically oriented on the support frame. A pair of ratchets is each of the ratchets is integrated into a respective one of the uprights. A mixing bowl is provided and the mixing bowl can pour contents of the mixing bowl when the mixing bowl is tipped. A pair of arms is each pivotally coupled to the bowl and each of the arms engages a respective one of the ratchets. Each of the ratchets rotates when the mixing bowl is tipped to pour the ingredients without requiring a user to support the mixing bowl.

A novel canister storage system, mixing system, canister assembly, dispensing system, and tracking system. In one or more embodiments, the systems are used for storing, mixing and dispensing fluids. In one application, the fluid includes one or more paint toners.

A conical mixer with two conical bodies that are sloped downward toward a discharge opening on a bottom, middle portion of the conical mixer. The conical mixer has a horizontally placed agitator axle with a plurality of agitator arms extending from the agitator axle. At least one paddle is attached to each agitator arms. As the agitator arms get closer to the middle, the length of the arms is increased. The conical mixer ensures proper mixing of the contents as well as using the slope of the conical bodies to assist in pushing the contents toward the discharge opening.

Disclosed is an apparatus for the processing of plastics, with a container with a rotatable mixing, where, in a side wall, an aperture is formed, where a conveyor is provided, with a screw rotating in a housing, wherein the imaginary continuation of the longitudinal axis of the conveyor in a direction opposite to the direction of conveying passes the axis of rotation, and wherein the ratio (V) of the active container volume (SV) to the feed volume (BV) of the container or of the cutter compactor (1), where V=SV/BV, is one where 4?V?30, where the active container volume (SV) is defined by the formula $\mathrm{SV}=D^3\frac{?}{4}$
and D is the internal diameter of the container, and where the feed volume (BV) is defined by the formula $\mathrm{BV}=D^2\frac{?}{4}.Math.H,$
where H is the height of the intake aperture.

The present invention relates to a mixing apparatus. A production unit produces a working fluid that is in a supercritical state or a subcritical state. A storage unit stores a material. A dissolving unit dissolves the material in the working fluid. A mixer mixes the material together in the presence of the working fluid. A material feed valve opens or closes a flow passage through which the material is to pass to be fed from the storage unit into the dissolving unit. A working fluid inflow valve opens or closes a flow passage through which the working fluid is to pass to flow into the dissolving unit from the production unit. A mixer inflow valve opens or closes a flow passage through which the working fluid and the material are to pass to flow into the mixer from the dissolving unit.

Disclosed are devices and methods for synthesizing products. The disclosed devices and methods may be used to synthesize products, e.g., pharmaceutical or therapeutic compounds (i.e., drugs), ceramics, catalysts, biological polymers (i.e., proteins, enzymes), cells, tissues, or combinations thereof. The devices and methods may be operated in a microgravity environment.