A homogenizer for homogenously blending a feedstock includes a separator, an agitator and a hopper integrated as a single unit in a common housing. The separator receives a material feed, in the form of a fluid medium carrying a composite feedstock, and separates the composite feedstock from the fluid medium. The agitator receives the separated composite feedstock from the separator, and mixes the composite feedstock to yield the homogenously blended feedstock. The hopper receives the homogenously blended feedstock from the agitator and holds the homogenously blended feedstock for release to either a processing machine or a storage container. The homogenizer is controlled by one or more control units that use signals received from a sensor in the hopper to control the delivery of a material feed to the homogenizer, and the flow of feedstock therethrough.

The present invention provides a method and system for providing on-site electrical power to a fracturing operation, and an electrically powered fracturing system. Natural gas can be used to drive a turbine generator in the production of electrical power. A scalable, electrically powered fracturing fleet is provided to pump fluids for the fracturing operation, obviating the need for a constant supply of diesel fuel to the site and reducing the site footprint and infrastructure required for the fracturing operation, when compared with conventional systems. The treatment fluid can comprise a water-based fracturing fluid or a waterless liquefied petroleum gas (LPG) fracturing fluid.

A liquid processing mixer is provided, comprising a mixing unit and a de-aeration vessel, the mixing unit being separated from the de-aeration vessel and in fluid connection with the de-aeration vessel, and wherein the liquid processing mixer further comprises at least one additive inlet arranged between the de-aeration vessel and a high shear mixing device of the mixing unit for introducing the additive downstream of the de-aeration vessel.

An ingredient blending apparatus is disclosed which blends a plurality of ingredients into a homogeneous blend. The apparatus includes a container which receives various ingredients in a prescribed amount. A vacuum motor has its intake side in communication with the interior of the container to suck the ingredients from the container and blow the same into a blending chamber. The ingredients blown into the blending chamber are mixed and recycled into the vacuum motor and the blending chamber until the ingredients are properly mixed or blended. When the ingredients are properly mixed or blended, they may be sent to an ingredient collection apparatus.

A microfluidic device includes a substrate, first and second capillary inlets, a microfluidic channel unit, an outlet disposed downstream of the microfluidic channel unit, and a suction member disposed downstream of the outlet. A first liquid is drawn into a first sub-channel and a main channel of the microfluidic channel unit through the first capillary inlet. A second liquid is drawn into a second sub-channel of the microfluidic channel unit through the second capillary inlet. The suction member provides a predetermined suction force to permit the second liquid to penetrate into the first liquid and to break up into droplets in the first liquid, thereby generating monodisperse emulsions.

A method and device with an interface for manufacturing a customised product by mixing. The present invention concerns a device for manufacturing a customised product, and preferably a customised cosmetic product, by mixing at least two components housed in respective containers, at least one of the containers being a capsule (103), and at least one other container being a pot (11) comprising a nozzle, preferably a pump nozzle, at least one of said containers comprising an identification code, said device comprising an interface for collecting customised data, for example on a mobile phone or tablet. The invention also concerns a method for manufacturing a customised cosmetic product by homogeneously mixing components, using customised user data.

This application discloses a slurry processing apparatus and a battery processing device. The slurry processing apparatus may include a slurry mixing assembly, a viscosity monitoring assembly, a controller, and a suction pump. The slurry mixing assembly may be configured to mix a slurry. The viscosity monitoring assembly may be configured to monitor a viscosity parameter of the slurry in the slurry mixing assembly. The controller may be separately connected to the slurry mixing assembly and the viscosity monitoring assembly, and the controller may be configured to receive the viscosity parameter and control operation of the slurry mixing assembly based on the viscosity parameter. The suction pump may have an inlet, and the inlet of the suction pump may be connected to the slurry mixing assembly through a first pipe for sucking the slurry in the slurry mixing assembly.

A seed treatment method, using a composition obtained extemporaneously by mixing at least one powder substance and an aqueous medium, comprising the steps consisting of: producing the mixture in an automatic and cyclic manner, in at least one first vessel (10; 10), by introducing into same first at least a portion of the aqueous medium and next the powder substance, the latter being sucked into the aqueous medium in the vessel by means of a vacuum created in the vessel, at least partially draining the content of the vessel, by means of at least one blast of compressed gas in the vessel, to a seed treatment device where the mixture is brought into contact with the seeds.

A mixing system is disclosed in which the system comprises a source of bone-graft or bone-graft-substitute material, a liquid source, and a vacuum source, at least one of the source of bone-graft or bone-graft-substitute material and the liquid source being in communication with the vacuum source. A valve assembly also forms part of the system, the valve assembly having a valve movable between a first position in which a first fluid passageway is created between the source of bone-graft or bone-graft-substitute material and the vacuum, and a second position in which a second fluid passageway is created between the source of bone-graft or bone-graft-substitute material and the liquid source, wherein, in the second position, the valve seals off the first fluid passageway, the vacuum source being adapted to generate a negative-pressure environment, relative to atmospheric pressure, within the valve assembly while the valve is in the first position. Methods of utilizing the aforementioned system are also disclosed.

A device mixes bone cement and stores parent components of the bone cement. The device has a cartridge comprising an interior, that is closed on one side by a movable delivery plunger, a receptacle comprising side walls for receiving a monomer liquid container that are closed at least in some regions. The receptacle has at least one deformable closed side wall, a screen and/or a filter arranged below the receptacle so that the contents of the opened monomer liquid container flow through the screen and/or the filter. The device further has a connecting line through which the monomer liquid is to be routed into the interior of the cartridge, a hollow cylinder which is connected to the connecting line and which is connected to the receptacle by way of a fluid connection so that the hollow cylinder is arranged in a fluid line between the receptacle and the interior of the cartridge. A pump plunger is arranged in the hollow cylinder, which is axially displaceable in the hollow cylinder, and an opening device, which is movably mounted against the deformable side wall of the receptacle. The opening device extends into the hollow cylinder, wherein, by pressing the pump plunger into the hollow cylinder, the opening device is to be pressed against the deformable side wall of the receptacle so that the deformable side wall deforms such that a monomer liquid container located in the receptacle is to be opened by the pressure of the opening device.