An impeller-free vortex generator apparatus for fluid mixing, including: a fluid tank including: a first fluid inlet port, the first fluid inlet port including a curved flow channel between a first sidewall segment of the fluid tank and a second sidewall segment of the fluid tank, a second fluid inlet port, and a fluid outlet port; and a first fluid intake duct in fluid communication with the first fluid inlet port; wherein the first fluid intake duct is provided substantially on a tangent to the first sidewall segment of the fluid tank and aligned to deliver a first fluid to an internal surface of the first sidewall segment.

An apparatus for manufacturing a cosmetic product including a mixing machine having a removable receiving device, a support defining a receiving housing, able to receive the 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 clamping mechanism, movable relative to the support and configured:
in an insertion position, not to interfere with the insertion and the withdrawal of the receiving device including capsules into/from the receiving housing, and
in a clamping position, to pinch a section of a capsule,
in which the clamping mechanism is a clamping wheel, movable in rotation about a clamping wheel axis.

The invention comprises a novel modular, generalizable meso-micro-nano-fluidic platform apparatus, design and methodology which in exemplary embodiments may be applied in conjunction with a novel external triggering and automation/feedback loop control mechanism deployed via computer to explore the phase space of single or double emulsification for applications including the encapsulation of hydrophilic active pharmacological ingredients (APIs). End use applications include the mass production of particulate encapsulation of hydrophobic or hydrophilic APIs with automatic or user-supervised feedback methodology to control and discover mass production or per-drug customized settings of interest for the manufacture of novel or extant therapeutics. This invention allows for a process to produce monodispersed particles of varying sizes and may be used to rapidly screen for optimal size for maximal bioavailability of API particles either on lab bench for in vitro dissolution or in vivo studies, and patient-specific handhelds for maximal drug inhalation.

An apparatus for dispersing particles in a fluid, comprising: a flow divider for receiving the fluid and for separating the fluid into a first fluid stream and a second fluid stream; first and second fluid branches for receiving the fluid streams; a branch joining section for receiving the fluid streams, the branch joining section having a collision zone for allowing the first and second fluid streams to collide; a first nozzle that is arranged in the first fluid branch; and a second nozzle is arranged in the second fluid branch, the first nozzle comprising an orifice that is followed by a fluid diverging section.

A volatiles consuming eductor system for coated scrap metal furnaces with separate delacquering and melt chambers. Motive gas is forced through an inlet into a mixing chamber in a direction opposite a suction port, creating a Venturi that draws gases from the delaquering chamber through the mixing chamber. The motive gas and the drawn gases mix and are forced through a discharge port, ignited, and injected into the melt chamber to help heat the melt chamber. A computer monitors process conditions and controls a regulator that adjusts the motive gas flow in response to those conditions.

In an autoclave apparatus for a high-pressure acid leaching process which advances leaching by stirring heated and pressurized material slurry and sulfuric acid by stirrers in compartments in an autoclave main body of a plurality of compartments, transfers slurry from an upstream side compartment to a downstream one to advance leaching, liquid flow ports for slurry transfer that open and close by doors are provided on the partition walls, the liquid flow ports for slurry transfer are installed at positions where the heights from the lowermost portion the autoclave to the center of gravity are 0.1 to 0.3 times an autoclave diameter and distances from the center lines of the partition walls to the center of gravity are 0.05 to 0.25 times the autoclave diameter, and the liquid flow ports for slurry transfer have shapes which do not reach end portions of the partition walls.

A technique facilitates mixing of cement slurry for use in a cementing application. At least one cement mixer is provided with a tank, e.g. a conical tank, having a powder cement blend inlet and a mixing liquid inlet. A cement slurry discharge may be positioned generally beneath the tank. A mixing assembly also is positioned below the tank and driven by a shaft. The mixing assembly is exposed to an interior of the tank and is used to mix the cement slurry when rotated by the shaft and to direct the cement slurry out through the cement slurry discharge. Additionally, a recirculation system comprises an inlet positioned to receive a portion of the cement slurry mixed in the mixing assembly. The recirculation system also comprises an outlet positioned to direct the portion back into the mixer to enhance mixing effects.

A roll assembly for increasing a surface area of a fluid, in particular for water treatment, including at least one shaft which in each case bears at least one roll, a drive for the at least one shaft, a fluid feed which is arranged above the respective roll and guides the fluid to the respective roll, and a collecting trough for the fluid, the collecting trough being assigned to the respective roll, wherein the roll has two lateral surfaces in the shape of cylinder jackets which are spaced apart in the radial direction, are each in the form of a mesh and project on the bottom side of the roll into the collecting trough.

This invention describes a design for a multiwell plate that contains integrated pumps that are used to stir each well of the plate. The device employs microfluidic logic technology to drive each peristaltic pump. This enables the plates to run autonomously, requiring only a static vacuum supply for power. The devices are entirely constructed out of low-cost polymers, with no electronics, and yet contains simple digital logic circuits to control the pumps. A stack of these plates may be run continuously in a standard cell culture incubator, allowing high-throughput culture of organoids.

Systems and methods for managing bulk material efficiently at a well site are provided. The disclosure is directed to a container support frame that is integrated into a blender unit. The support frame is used to receive one or more portable containers of bulk material, and the blender unit may include a gravity feed outlet for outputting bulk material from the containers directly into a mixer of the blender unit. The blender unit with integrated support frame may eliminate the need for any subsequent mechanical conveyance of the bulk material (e.g., via a separate mechanical conveying system or on-blender sand screws) from the containers to the mixer. As such, the integrated blender unit may be lighter weight, take up less space, and have a lower cost and complexity than existing blenders.