The present disclosure belongs to the technical field of gel material processing, and discloses processing equipment and a processing technology of a gel microsphere material. The processing equipment comprises a mixing barrel, wherein a motor is installed at the top of the mixing barrel; a rotating rod is arranged in the mixing barrel; the rotating rod is fixedly connected to the output end of the motor; a fan-shaped impeller is installed at the bottom end of the rotating rod; the bottom of the rotating rod communicates with a gas conveying pipe; a shunting ring is fixedly connected to the inner side wall of the mixing barrel; the bottom of the rotating rod is fixedly connected with the fan-shaped impeller; and the gas conveying pipe is arranged at the bottom of the mixing barrel to inflate a raw material solution in the mixing barrel, when bubbles float in the solution, the solution can be stirred, and then under the cooperation of the fan-shaped impeller at the bottom of the rotating rod, the raw material solution of the gel microsphere material is stirred more quickly and more uniformly in the mixing barrel compared with the raw material solution only stirred by the fan-shaped impeller.

The present disclosure belongs to the technical field of gel material processing, and discloses processing equipment and a processing technology of a gel microsphere material. The processing equipment comprises a mixing barrel, wherein a motor is installed at the top of the mixing barrel; a rotating rod is arranged in the mixing barrel; the rotating rod is fixedly connected to the output end of the motor; a fan-shaped impeller is installed at the bottom end of the rotating rod; the bottom of the rotating rod communicates with a gas conveying pipe; a shunting ring is fixedly connected to the inner side wall of the mixing barrel; the bottom of the rotating rod is fixedly connected with the fan-shaped impeller; and the gas conveying pipe is arranged at the bottom of the mixing barrel to inflate a raw material solution in the mixing barrel, when bubbles float in the solution, the solution can be stirred, and then under the cooperation of the fan-shaped impeller at the bottom of the rotating rod, the raw material solution of the gel microsphere material is stirred more quickly and more uniformly in the mixing barrel compared with the raw material solution only stirred by the fan-shaped impeller.

An apparatus for agitating liquid foodstuff, comprising a whisk that includes a magnetic rotor of a brushless electromotor assembly, and a main body including a liquid foodstuff container in which the whisk is receivable such that it is rotatable around a rotation axis thereof, and a stator of the electromotor assembly. The stator is configured to electromagnetically drive the rotor in rotation, and includes at least one magnetic sensor configured to provide a signal that reflects positional changes of the magnetic rotor relative to the magnetic sensor. The main body also includes a controller configured to detect an initial, manually effected rotational movement of the whisk around its rotation axis from the signal of the magnetic sensor, and, once such initial movement of the whisk is detected, to operate the apparatus independent of said initial, movement.

A carbonated beverage maker includes a water reservoir, a carbon dioxide creation chamber, and a carbonation chamber. The water reservoir holds ice water and has a first impeller and a shroud surrounding the first impeller. The carbon dioxide creation chamber contains chemical elements and receives warm water. The chemical elements react with each other to create carbon dioxide when the warm water is introduced to the carbon dioxide creation chamber. The carbonation chamber is connected to the water reservoir and the carbon dioxide creation chamber. The carbonation chamber has a second impeller that includes a stem portion and blades. The stem portion and the blades define conduits therein. The blades create a low pressure region in a lower portion of the carbonation chamber such that carbon dioxide from the carbon dioxide creation chamber flows through the conduits to the low pressure region.

A gas-saturated liquid generator having a vessel of the generator, a hollow bell in its upside down position located with a tube for gas supply, and a mixer situated in the area for saturated liquid covered by the bell is disclosed. The entire bell is submerged below the surface of the saturated liquid. On a shaft projecting from a driving equipment, the mixer provided with a foaming spring is situated. The mixer provided with a magnetic carrier seated rotatably on the protrusion formed by a bulge in the bottom part of the generator vessel may be used. The preferred bell forms are dome-shaped, cylindrical or conical.

A method and system for converting a single-use liner lined bottom-mix mixing vessel to a single-use liner lined top-mix missing vessel. A bottom mount magnetic impeller drive is replaced by a top mounted impeller drive. A support frame is placed on an upper portion of the mixing vessel and has an articulated joint supporting a motor drive assembly. A top-mix single-use liner is inserted into the mixing vessel. An impeller drive shaft is inserted through a rotary hub seal in the liner to drive an internal impeller. The rotary hub seal is located by a hub lock assembly attached to the motor drive assembly.

A method and system for converting a single-use liner lined bottom-mix mixing vessel to a single-use liner lined top-mix missing vessel. A bottom mount magnetic impeller drive is replaced by a top mounted impeller drive. A support frame is placed on an upper portion of the mixing vessel and has an articulated joint supporting a motor drive assembly. A top-mix single-use liner is inserted into the mixing vessel. An impeller drive shaft is inserted through a rotary hub seal in the liner to drive an internal impeller. The rotary hub seal is located by a hub lock assembly attached to the motor drive assembly.

An impeller, for example, a Rushton impeller for a bioreactor system is disclosed. The impeller includes a hub, optionally including a slot, a plurality of blades, and one or more turbulators. The plurality of blades is disposed along a circumferential direction of the hub and spaced apart from each other. Each of the plurality of blades is coupled to at least a portion of a circumference and/or a top surface of the hub. Each blade of the plurality of blades includes a pressure face and a suction face. The one or more turbulators is disposed on at least a portion of the suction face, the pressure face, or both, of a blade of the plurality of blades.

A mixing system (10) including a base module (12), a mixing unit (26), and an enclosure (14). The base module (12) includes a base support (16), a drive unit (18) disposed within the base support (16), a drive shaft (22) coupled to the drive unit (18), and a drive head (24) coupled to the drive unit (18) via the drive shaft (22) and disposed within the base support (16). The drive head (24) includes a first magnet (25). The mixing unit (26) includes a guide element (28) and an agitator (30) slidably coupled to the guide element (28). The agitator (30) includes a second magnet (32) and at least one vane (34). The enclosure (14) is coupled to the base support (16) encloses the guide element (28) and the agitator (30). The drive unit (18) and the drive head (24) are configured to generate a linear pulsating movement of the agitator (30) along the guide element (28) for mixing a fluid medium (47) within the enclosure (14).

A method for maintaining a fluidic dispensing device includes providing a fluidic dispensing device having a fluid reservoir containing fluid, the fluid reservoir being defined in part by a base wall, and having a stir bar located in the fluid reservoir adjacent to the base wall, and having a fluid ejection chip having a fluid ejection direction; positioning the fluidic dispensing device at a predetermined orientation, wherein the fluid ejection direction is oriented in a range of upward vertical, plus or minus 90 degrees; and rotating the stir bar in a first rotational direction starting with a first rotational speed and increasing rotational velocity from the first rotational speed to a second rotational speed.