Apparatus and system for preparing an ice-containing tea or coffee beverage. The apparatus (300) comprising a beverage concentrate reservoir (360), a sweetener concentrate reservoir (361) and a water pre-chiller (312). A first pre-mixer (362) for mixing beverage concentrate supplied from the beverage concentrate reservoir with water supplied from the water pre-chiller, a second pre-mixer (363) for mixing sweetener concentrate supplied from the sweetener concentrate reservoir with water supplied from the water pre-chiller. A mixing chamber (364) for mixing an output from the first pre-mixer with an output from the second pre-mixer to form a beverage liquor, a cooling unit (310). An ice-generating system (311), a beverage product circuit for supplying the beverage liquor from the mixing chamber to the ice-generating system and a cooling circuit for supplying coolant from the cooling unit to the ice-generating system to cool the beverage liquor and to thereby form a plurality of ice crystals within the beverage liquor. A beverage dispensing outlet (303) is also provided.

The problem to be solved by the present invention is to provide a method for producing an aqueous pigment dispersion that has certain dispersion stability with which the formation of coarse particles with time and the settling of a pigment and the like with time can be reduced and that can be used for producing an ink having excellent discharge stability. The present invention relates to a method for producing an aqueous pigment dispersion, the method including kneading a composition including a pigment including one or more materials selected from the group consisting of a violet pigment, a green pigment, and an orange pigment and a resin, the composition having a nonvolatile content of 50% by mass or more, under predetermined conditions and subsequently performing a centrifugation treatment.

Methods for handling bulk material in a manner that reduces dust, noise, and emissions are provided. The presently disclosed techniques use portable containers to transfer bulk material from a transportation unit to a blender inlet. The containers may be carried to the location on the transportation unit, where a hoisting mechanism is used to remove the container from the transportation unit and place it in a desired location. When bulk material is needed at the blender inlet, the hoisting mechanism may position the container of bulk material onto an elevated support structure. Once on the support structure, the container may be opened to release bulk material to a gravity feed outlet, which routes the bulk material from the container directly into the blender inlet. The disclosed containerized bulk material transfer system and method allows for reduced dust, noise, and emissions on location.

Systems and methods describe continuously and progressively hydrating material, such as food material for meat analogue products. First, material is provided to be conveyed through a material passage between an exterior tube and a rotating inner shaft, with the rotating inner shaft including one or more agitation and/or progression features. The progression features could be, e.g., a series of imbricated protruding filled paddles arranged in a helical pattern, while the agitation features could take the form of, e.g., unfilled hoops, hooks, or paddles. Concurrent to conveying and hydrating the material through the material passage, a number of lumps, clumps, and/or unhydrated pieces of the material are broken up via one or more agitation features configured to produce uniform hydration and consistent dispersal of the material. Also concurrently or subsequently, water is continuously and/or progressively provided to the material to produce hydrated material particles.

The present invention is a dust abatement device that secures over a container. Powdery material, such as plaster, cement, grout or the like, is poured through the device, and mixed with water inside the container. The device has a mounting sleeve and radial manifold. The manifold forms a radial pneumatic channel with a circumferentially disbursed air intake that generates a radially uniform airflow to draw in airborne dust that would otherwise escape to the surrounding air. The manifold is connected to a vacuum with an air filter, and generates a dust shield zone above and around the device, which only extends down from the manifold a few inches. The manifold also funnels material and water into the container, and forms an inner eave that spaces material and water from the air intake, and forms a splash guard to retain upwardly projected splashes of material and water inside the container.

An electrically driven oilfield blender system is configured to utilize electric motors as electric prime movers to prepare frac slurry and move the frac slurry to an oilfield pressure pumping system or pressure pumper that pumps the frac slurry into a subterranean formation. Each of the prime mover electric motors may operate at a fixed or constant rated speed and may be connected to a transmission that can drive a device such as a feed pump for a mixing tub or an auxiliary device at a variable speed. An electro-hydraulic motor start system includes an electric motor that powers a hydraulic pump. The hydraulic pump drives hydraulic motors that pre-rotate the prime mover electric motors to their rated speeds before they are energized.

Systems and methods for recovering dry bulk material from a blender at a job site are provided. The systems include at least one container having in which dry bulk material can be placed and a skid-mounted vacuum unit comprising a tank having an interior space and an outlet for interfacing with the inlet of the container when the vacuum unit is positioned proximate to the container, a vacuum pump in communication with the interior space of the tank, and a conduit coupled to an inlet of the vacuum pump for interfacing with an inlet of a blender.

In drug mixing devices of disclosed embodiments, a main flow path extending from one end configured to allow liquid inside the first container to enter the main flow path therethrough to another end configured to allow liquid inside the second container to enter the main flow path therethrough, and a branch flow path branching from the main flow path are formed. The drug mixing device includes a body including a first connection part configured to be coupled with the first container and a second connection part configured to be coupled with the second container, and a backflow prevention part disposed in a partial flow path of the main flow path extending to the one end with reference to the connection point of the main flow path and the branch flow path, the backflow prevention part being configured to prevent liquid from flowing from the connection point to the one end.

The present disclosure relates to a process for producing homogeneous solutions comprising dissolved polyacrylonitrile-based polymer, and a system suitable therefor. The homogeneous polymer solutions produced by the process described herein may be used for producing carbon fiber, typically carbon fiber used in manufacturing composite materials.

A piping manifold that combines multiple solids fluidizers with a common motive fluid connection and a common slurry discharge connection. The manifold utilizes flexible pipe materials to connect the individual fluidizer feed and discharge connections to a distribution and a collection hub that are combined into a single structure with a common dividing plate between the distribution and collection chambers. An adjustable support structure that allows adjustable positioning of the individual fluidizers without customized design, manufacturing or modification of the manifold.