Provided are a system for manufacturing dispersion liquid of carbon nanotubes and a method of manufacturing a dispersion liquid of carbon nanotubes using the same. The system includes; a mixing device supplied with solvent and carbon nanotubes, and storing a admixture of the solvent and the carbon nanotubes; a first dispersion device connected to the mixing device, performing a primary dispersion of the carbon nanotubes by an operation of a rotor and a stator, and then performing a secondary dispersion to form bent portions in the carbon nanotubes while discharging the carbon nanotubes through penetration holes of the stator; and a second dispersion device performing a tertiary dispersion of the carbon nanotubes to selectively cut the bent portions of the carbon nanotubes by irradiating a laser when the secondarily dispersed admixture recirculates to the mixing device.

A device for mixing powders by cryogenic fluid, characterised in that it comprises at least: a chamber for mixing powders, comprising a cryogenic fluid; a chamber for supplying powders in order to allow the powders to be introduced into the mixing chamber; means for agitation in the mixing chamber so as to allow the mixing of the powders placed in suspension in the cryogenic fluid.

To provide a microparticle-containing liquid dispersing device capable of dispersing microparticles containing cells, a microparticle sedimentation suppression method, a microparticle sorting or measuring device, and a microparticle sedimentation suppression vibrator. The microparticle-containing liquid dispersing device includes: a microparticle sedimentation suppression vibrator including a fixture configured to connect and hang on a bag containing a microparticle-containing liquid, the microparticle sedimentation suppression vibrator hanging the bag in a vertically downward direction; and a stand that hangs the bag.

The invention relates to a food processing system (100) for preparing an edible mass of a food product starting from a raw food material, the system comprising: one or a plurality of food containers (20), each one comprising a raw food material in form of dehydrated material and/or paste and/or chunks; one or a plurality of dispensing and reconstituting chambers (10), each chamber being associated to at least one food container (20), each of the chambers (10) comprising a variable and/or exchangeable reconstitution and deposition device configured for hydrating and/or structuring and/or reconstituting in batches the raw food material provided by the one or more food containers (20) in order to create a homogeneous edible mass of food product, the device being further configured to deposit in-line with a controlled flow the edible mass of food product once prepared. The invention further relates to a method for operating a food processing system (100) as the one described in order to prepare an edible mass of food product starting from raw food material: the information on the kind of raw food material and on its processing is retrieved from identification means on the one or more food containers (20) and/or from a connected database, in order to process the raw food material in the one or more of the dispensing and reconstituting chambers (10) according to a certain recipe, acting on the hydration ratio and/or mixing speed and/or mixing time and/or temperature and/or viscosity and/or texture

A system for making and using a ground product that includes one or more of: a reactor operated to react a guar split with a reagent at a reaction temperature in a range of 120 F. to 180 F. to form a guar derivative, and a treatment and transfer section for optionally treating the guar derivative and transferring the guar derivative to a co-grinder. The co-grinder is operably associated with a heated vacuum system and is operated to co-grind an acid with the guar derivative to form a ground product.

A slurry injection system includes low and high pressure clear fluid manifolds. Low pressure clear fluid is pressurized and communicated to high pressure manifold. A blender unit communicates slurry through a sensor system that generates a flow rate signal and a density signal of the low pressure slurry. The slurry pressurizer is in fluid communication with the high pressure clear fluid manifold through a bypass pump, a mixer, the blender unit and the low pressure clear fluid manifold. The slurry pressurizer forms high pressure slurry that is communicated to the mixer and communicates fluid to the low pressure clear fluid manifold. The mixer mixes the high pressure slurry and high pressure clear fluid from the high pressure clear fluid manifold to form a mixture that is communicated to a slurry injection site. A controller controls the bypass pump using the flow rate and density to control a density of slurry.

A slurry injection system includes low and high pressure clear fluid manifolds. Low pressure clear fluid is pressurized and communicated to high pressure manifold. A blender unit communicates slurry through a sensor system that generates a flow rate signal and a density signal of the low pressure slurry. The slurry pressurizer is in fluid communication with the high pressure clear fluid manifold through a bypass pump, a mixer, the blender unit and the low pressure clear fluid manifold. The slurry pressurizer forms high pressure slurry that is communicated to the mixer and communicates fluid to the low pressure clear fluid manifold. The mixer mixes the high pressure slurry and high pressure clear fluid from the high pressure clear fluid manifold to form a mixture that is communicated to a slurry injection site. A controller controls the bypass pump using the flow rate and density to control a density of slurry.

A method for producing a suspension, wherein plant parts are comminuted in portions and mixed with water so that the water and the plant parts form the suspension, and a pomace remaining from the plant parts is separated from the suspension. A device for producing a suspension, the device including a mixing chamber and a mixing element in the mixing chamber for mixing a portion of comminuted plant parts with water so that the water and the plant parts form the suspension, and an outlet on the mixing chamber for letting the suspension out of the mixing chamber so that a pomace remaining from the plant parts is retained in the mixing chamber. In order to accelerate production, the plant parts are mashed to a pulp while the water is pressed at a positive pressure through the pulp and through a filter which retains the pomace.

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.

A method, apparatus, and system for obtaining a solution from a solid product are disclosed. A solid product is housed in a dispenser. A liquid is introduced into the housing of the dispenser to interact with the solid product to form a solution. To control the concentration of the formed solution, the turbulence of the liquid introduced to the dispenser is controlled and adjusted either manually or on a real time basis to account for varying characteristics of either or both of the solid product and the liquid. The dispenser will adjust the turbulence based on the characteristics to maintain a formed solution within an acceptable range of concentration. The concentrated solution can then be discharged from the dispenser to an end use application.