The method of producing a colored powder of a polymeric material includes the steps of selecting a feedstock of said polymeric material, pulverizing said polymeric material in a pulverizer to produce a powder, moving the powder directly from the pulverizer to a mixer; spraying a liquid formulation including a colorant into the powder within the mixer, and mixing the liquid formulation and powder.

A batch mixer is equipped with a plunger for pushing material from the batch mixer. The batch mixer includes a mixer tank structured to accommodate material. The mixer further includes a mixer head comprising at least one blade structured to blend the material within the mixer tank. The mixer further includes a plunger mechanism structured to push the blended material directly from the mixer tank.

An apparatus for converting a dry material into a liquid concentrate includes a mixing vessel having an outlet opening, a dispenser for dispensing a predetermined weight of a dry material at a predetermined drop rate onto a predetermined drop location within the vessel, an inlet pipe connectable to a source of liquid for introducing a liquid into the vessel; a sensor for sensing the volume of liquid within the vessel; a pump for supplying a pressurized flow of recirculating liquid to the vessel; and a first, a second and a third agitating nozzle mounted within the vessel. Each agitating nozzle is operative to produce a jet of liquid oriented in a predetermined direction within the vessel. The nozzles are cooperable to generate within the vessel a moving body of liquid into which a dry material dispensed into the vessel is able to dissolve or to disperse.

A batch preparation system for quickly and efficiently mixing materials with a fluid, such as to fill an agricultural reservoir tank. The batch preparation system generally includes a frame, a tank unit comprising a plurality of tanks connected to the frame, and a transfer system for mixing materials stored in the tanks with fluids being pumped from a fluid source. The tanks are interconnected to form a unitary tank unit which is positioned on the frame. The transfer system includes a manifold pipe which is fluidly connected to each of the tanks. An eductor is connected to the manifold such that the materials from each tank are drawn by suction through the eductor into a mixing conduit, where the materials are mixed with the fluid from the pump. The resulting mixture is dispensed through a transfer outlet, such as to a reservoir tank.

A stirring apparatus includes a bed, a column, a revolution shaft, a revolution driving device, a support member, and a stirring unit. The revolution shaft is supported by the column and extends in a horizontal direction. The revolution driving device rotates the revolution shaft about a first center line being an axis of the revolution shaft. The support member is fixed to the revolution shaft. The stirring unit includes cups and a self-rotation mechanism. The cups are disposed on a circumference centered on the first center line via the support member. The self-rotation mechanism rotates the cups about a second center line passing through a center of the cups. The cups is provided in an inclined manner so that a perpendicular from the center of a bottom plate to the first center line is shorter than a perpendicular from the center of an opening to the first center line.

A cleaning system for washing an internal surface of a container located on a vehicle, the cleaning system comprising an elongate boom with at least one nozzle located at a first end of the boom, a support assembly for supporting the boom, wherein the boom is movable with respect to the support assembly, a controller configured to control movement of the boom, and a vehicle identification system comprising an identification reader configured to identify the vehicle and communicate with the controller, wherein one or more parameters of the vehicle can be stored on or retrieved from the vehicle identification system upon identifying the vehicle, and wherein the boom is configured to extend into the container to wash the internal surface based on the one or more parameters.

A gas mixing system for semiconductor fabrication includes a mixing block. The mixing block defines a gas mixing chamber, a first gas channel fluidly coupled to the gas mixing chamber at a first exit location, and a second gas channel fluidly coupled to the gas mixing chamber at a second exit location, wherein the first exit location is diametrically opposite the second exit location relative to the gas mixing chamber and the second gas channel has a bend of 90 degrees or less between an entrance of the second gas channel and the second exit location.

The various embodiments of the present invention generally relate to an automated apparatus, wherein the automated apparatus is configured to formulate a target entity, thereby developing formulations of the target entity by using a high throughput screening (HTS) procedure and method of employing the presented automated apparatus is also disclosed herein. Other advantages that are understood from the present disclosure will further be apparent to the reader.

An apparatus has a container conveyor configured to transport a container to locations within the apparatus. The locations include a liquid station comprising a liquid source configured to dispense a liquid to the container, an additive station comprising an additive source configured to dispense an additive to the container, a distribution station accessible to a user and configured to receive the container, and a blending station separate from the liquid station, the additive station, and the distribution station. The blending station includes a blending mechanism configured to blend, in the container, the liquid and the additive to form a mixture. The blending station also has a cleaning chamber with a cleaning mechanism configured to clean remains of the mixture from the blending mechanism and the cleaning chamber.

The present application relates to a cleaning apparatus and a stirring device. The cleaning apparatus comprises a mounting base, nozzles and a driving mechanism. The mounting base is configured to be rotatable around a set direction. The nozzles are arranged on the mounting base, and the driving mechanism is arranged on the mounting base and used for driving the nozzles to swing relative to the mounting base.