An apparatus for mixing comprising a vessel 302 for holding a product comprising a liquid base and an ingredient, a rotor 304 for providing a first flow 306 of said product inside said vessel and a double agitator for providing a second flow 312 of said product inside said vessel. The double agitator comprises a first agitator 308 arranged to rotate in an outer section of said vessel, and a second agitator 310 arranged to rotate in an inner section of said vessel.

An apparatus for making a battery slurry is disclosed. The apparatus comprises a vacuum system providing a vacuum environment, a dry powder mixing device mixing a plurality of powdery materials uniformly to obtain a dry powder, a kneading device kneading the dry powder with the first part solvent to form a doughy mixture, and a high speed dispersing device dispersing the doughy mixture to the second part solvent to form the battery slurry. The vacuum system, the dry powder mixing device, the kneading device, and the high speed dispersing device are connected to each other.

Present invention creatively makes convenient for any person using beverage to blend powder with liquid uniformly without use of shaking motion or battery and thereby preventing from spilling and running out batteries. Invention of unique reverse planetary gears system and side arm stirrer with window paddle has made possible convert torque of finger to multiple rotation of stirrer in order achieve efficient uniform blending. Moreover, this invention takes full advantage of removable snap mechanism to assemble and disassemble protein blender cup which is very necessary for washing every single parts to achieve highest sanitization. In short, this invention helps consumer to have protein blender cup which doesn't require shaking or battery and can be completely sanitized without any struggle.

The present invention relates to a mixer, preferably to a ring-pan mixer, having a mixing trough and a mixer rotor that is rotatable via a drive motor about a substantially vertical axis of rotation and at which at least one mixing tool drivable via a separate drive motor is arranged rotatable about a separate axis of rotation, wherein the drive speeds of the mixer rotor and of the at least one mixing tool can be set independently of one another, with the mixer rotor and the at least one mixing tool being able to be set via a transmission independently of one another.

The invention relates to an agitator for mixing of fluids with different viscosities, wherein the agitator has a main shaft rotatable about an axis of rotation and paddles supported by the main shaft, each paddle comprising a paddle shaft extending at an angle relative to the axis of rotation of the main shaft ranging between 20° and 40°, and the paddles being arranged around the main shaft spaced by an angle of 90° relative to one another, and the paddles with the agitator being rotatable about the axis of rotation of the main shaft and also about the respective paddle shaft axis, wherein a radial first distance of the paddle shaft axes relative to the axis of rotation at a lower end of the paddle shafts facing away from the main shaft is larger than a radial second distance of the paddle shaft axes relative to the axis of rotation at an upper end of the paddle shafts facing the main shaft.

A method for forming a vacuum insulated structure using a prepared core material includes preparing a powder insulation material defining a bulk density, pre-densifying the powder insulation material to form a pre-densified insulation base, crushing the pre-densified insulation base into granular core insulation to define a core density of the granular core insulation, disposing the granular core insulation having the core density into an insulating cavity defined within an insulating structure and expressing gas from the interior cavity of the insulating structure to further densify the granular core insulation to define a target density. The granular core insulation defines the target density disposed within the insulating structure defines the vacuum insulation structure, wherein the target density defines a density in the range of from approximately 80 grams per liter to approximately 350 grams per liter.

An automated production system is disclosed herein. One aspect of the present technology, for example, is directed toward an automated system for the continuous production of baked bread. The system can include a priming assembly having a dry ingredients priming unit and a wet ingredients priming unit. The dry ingredients priming unit can include a vertically-oriented hopper and a screw positioned within an interior region of the hopper, wherein the first screw extends along the central longitudinal axis of the hopper and is configured to rotate about its own central longitudinal axis. The system can also include a mixing assembly, a forming assembly, an oven, and a controller. The controller can be coupled to the priming assembly and configured to adjust the amount of dry ingredients delivered from the hopper to the mixing chamber by controlling rotation of the screw.

A food processing machine includes a head extending over a bowl receiving location, the head including an output shaft driven in a planetary manner. At least a first food processing tool and a second food processing tool can be changed in and out of the machine to be driven by the output shaft. A controller and associated tool detection system is configured to identify whether the first food processing tool or the second food processing tool is mounted on the machine and to select a stored load profile that is linked to the identified food processing tool.

An automated production system is disclosed herein. One aspect of the present technology, for example, is directed toward an automated system for the continuous production of baked bread. The system can include a priming assembly having a dry ingredients priming unit and a wet ingredients priming unit. The dry ingredients priming unit can include a vertically-oriented hopper and a screw positioned within an interior region of the hopper, wherein the first screw extends along the central longitudinal axis of the hopper and is configured to rotate about its own central longitudinal axis. The system can also include a mixing assembly, a forming assembly, an oven, and a controller. The controller can be coupled to the priming assembly and configured to adjust the amount of dry ingredients delivered from the hopper to the mixing chamber by controlling rotation of the screw.

A method for forming a vacuum insulated structure using a prepared core material includes preparing a powder insulation material defining a bulk density, pre-densifying the powder insulation material to form a pre-densified insulation base, crushing the pre-densified insulation base into granular core insulation to define a core density of the granular core insulation, disposing the granular core insulation having the core density into an insulating cavity defined within an insulating structure and expressing gas from the interior cavity of the insulating structure to further densify the granular core insulation to define a target density. The granular core insulation defines the target density disposed within the insulating structure defines the vacuum insulation structure, wherein the target density defines a density in the range of from approximately 80 grams per liter to approximately 350 grams per liter.