Provided is a production method with which a large amount of particle mixture in which two or more types of particles are mixed can be easily produced. The production method is for producing a particle mixture in which two or more types of particles are mixed, and includes the following steps (1) and (2): (1) a step of adding a first additive to first particles and mixing the first additive with the first particles using a first mixer; and (2) a step of introducing the two or more types of particles including the first particles mixed with the first additive and second particles into a blender container of a gravity blender, and mixing the two or more types of particles inside the blender container.

The invention relates to a tubing device (40) for sterile media comprising a container (54) for storing sterile media, a discharge port (52) for discharging liquid sterile media, an inlet port (41) for introducing fluid into the tubing device and a multiple-way-connector (50), wherein the multiple-way-connector (50) is connected to the container (54), the discharge port (52) and the inlet port (41), and an apparatus (80) for preparing, mixing and discharging a sterile medium for use with a tubing device (40), comprising a water inlet port (41) for introducing water, a water outlet port (87) configured to be connected to the inlet port (41) of the tubing device (40), a fluid pump (82) for conveying the fluid, the fluid pump (82) is connected to the fluid inlet port (81) and the water outlet port (87) and a container support (88) for supporting the container (54) of the tubing device (40).

An apparatus for creating an emulsion, including: an inlet chamber; a channel comprising a length L, height H, an inlet and an outlet, and walls having surface energies, the channel inlet adjacent to the inlet chamber. The channel inlet walls have a first surface energy and the outlet walls have a second surface energy substantially different from the first surface energy. An outlet chamber is disposed adjacent to the channel outlet, the outlet chamber height H2 being greater than the channel height H.

A mixing and dispensing device and method. In particular, the device used by the applied method reduces the risk of chlorine gas formation while providing a stable, effective and safe disinfectant in the form of a hypochlorous add and sodium hypochlorite mixture. The mixing and dispensing device includes a highly concentrated disinfectant and dilutes the concentrate through the device while simultaneously mixing the concentrate with a dilute solution of an organic acid. The two diluted solutions are mixed without production of chlorine gas and to a level of safety before being dispensed to produce the stable, effective and safe neutral pH sodium hypochlorite solution disinfectant in the form of a hypochlorous add and sodium hypochlorite mixture. The mixing and dispensing device can be in the form of a kit for retrofitting into institutions or isolated, remote areas in need thereof or for off the shelf use in the home.

A system and method is provided for direct condensing steam heating of oil sands process slurry streams including viscous bitumen froth and tailings products streams. Slurry viscosities greater than that of water increase cavitation and vibration issues. High solids content exacerbate component erosions. Difficult, and competing, steam and slurry interactions are managed by steam nozzle arrangements and management of steam injection at sub-sonic velocities based on a ratio of the slurry back-pressure Pb and steam supply delivery pressure Po.

A mixer is adapted to include: a flow path forming member formed with an internal flow path; and an insertion member inserted into the internal flow path, in which: the inner circumferential surface forming the internal flow path in the flow path forming member or the outer circumferential surface of the insertion member is formed with a first groove and a second groove merging with the first groove and branching from the first groove, and the inner circumferential surface and the outer circumferential surface are fitted to each other; and the first groove and the second groove are formed as a mixing flow path for, between the flow path forming member and the insertion member, branching and merging fluid flowing from one side of the internal flow path and guiding the fluid to the other side of the internal flow path.

A mixing device is configured for the continuous provision of a gelling mass for a molding machine. The mixing device includes an inlet, an outlet and a conduit section which is situated between the inlet and the outlet and into which at least one admixing conduit runs out, via which admixing conduit a substance to be admixed can be fed such that the substance to be admixed is mixed with a base mass which is fed through the inlet, in a mixing region in the conduit section. The mixing device is configured in a manner such that the spatial distance between the outlet and the mixing region in which the substance to be admixed is mixed with the base mass, can be changed. A molding machine with such a mixing device and to a method for processing a flowable and gellable mass are provided.

A multi-lumen mixing device is described. The multi-lumen mixing device includes a mixer body having an inlet portion and an outlet portion. The multi-lumen mixing device also includes an array of capillary channels within the mixer body, in which each capillary channel has approximately a same length. An inlet for each of the capillaries is proximate to the inlet portion and an outlet for each of the capillaries is proximate to the outlet portion. The array of capillary channels has at least three different cross-sectional areas.

The invention generally relates to a mixing device. In certain embodiments, devices of the invention include a fluidic inlet, a fluidic outlet, and a chamber, the chamber being configured to produce a plurality of fluidic vortexes within the chamber.

A mixing device may define a mixing chamber including a vortex mixing portion, a primary gas path along which a first gas stream moves to the vortex mixing portion, and a secondary gas path along which a second gas stream moves to the vortex mixing portion. The mixing device may have a mixer body, an outer gas guide positioned in the mixer body to guide the second gas stream to the vortex mixing portion, and an inner gas guide at least partially positioned in the mixer body to guide the first gas stream to the vortex mixing portion. A portion of the inner gas guide may be positioned in the outer gas guide to form an annular gap between the gas guides to define the secondary gas path about the primary gas path to create a vortex of the first and second gas streams in the vortex mixing portion.