A fluid mixing system includes a container, such as a flexible bag, bounding a compartment. A flexible drive line is disposed within the compartment, the drive line having a first end rotatably connected to a first end of the container and an opposing second end rotatably connected to a second end of the container. At least one mixing element, such as an impeller, can be coupled with the flexible drive line. Rotation of the drive line facilitates rotation of the impeller within the container.

A fluid mixing system includes a container, such as a flexible bag, bounding a compartment. A flexible drive line is disposed within the compartment, the drive line having a first end rotatably connected to a first end of the container and an opposing second end rotatably connected to a second end of the container. At least one mixing element, such as an impeller, can be coupled with the flexible drive line. Rotation of the drive line facilitates rotation of the impeller within the container.

A mixer for a food product includes a vessel, an stator arranged in the vessel, and a rotor to rotate the food product relative the stator. The stator is displaceable relative the rotor by a movement along a stator guide. The stator guide includes an interior cavity being enclosed by a wall extending into the vessel, and a first magnetizable material is arranged inside the cavity. The stator includes a second magnetizable material, wherein a magnetic field between the first and second magnetizable materials generates a force that moves the stator along the stator guide for displacement of the stator relative the rotor.

A fluid mixing system includes a collapsible container bounding a compartment and extending between a first end and an opposing second end. An elongated continuous drive line is at least partially disposed within the compartment of the container. A first portion of the drive line is laterally spaced apart from a second portion of the drive line, and the first portion of the drive line and the second portion of the drive line are rotatable within the compartment of the container.

A fluid mixing system includes a container, such as a flexible bag, bounding a compartment. A flexible drive line is disposed within the compartment, the drive line having a first end rotatably connected to a first end of the container and an opposing second end rotatably connected to a second end of the container. At least one mixing element, such as an impeller, can be coupled with the flexible drive line. Rotation of the drive line facilitates rotation of the impeller within the container.

A mechanically driven agitator for use in bioprocessing, including a seal housing providing an integral seal around the agitator shaft is provided. Additionally, a fluid mixing assembly comprising a container and the agitator, as well as a support assembly for supporting the fluid mixing assembly, the support assembly further comprising a mounting assembly for lockably engaging the seal housing, are also provided.

Disclosed in an embodiment of the present application is a mixing apparatus, mixing machine, and cooking utensil. A mixing apparatus that can be fitted to an electric motor assembly. The electric motor assembly is able to drive the mixing apparatus to rotate for mixing food ingredients. The mixing apparatus comprises a connection part, stirring rods extended from the connection part and stirring bars. The positions at which the stirring bars are fitted to the stirring rods can be adjusted based on the type and quantity of food ingredients to increase mixing uniformity.

A fluid mixing system includes a flexible bag having an interior surface bounding a compartment. A retainer is coupled to the flexible bag, the retainer having a retention cavity formed thereon that communicates with the compartment of the flexible bag. An elongated tubular connector has a first end coupled to the flexible bag and an opposing second end projecting into the compartment thereof. An impeller is disposed within flexible bag and is coupled with the tubular connector. A steady support is mounted on the second end of the tubular connector and terminates at a distal nose, the distal nose being freely disposed within the retention cavity of the retainer so that the steady support can rotate within the retention cavity relative to the retainer.

A universal wall and bridge mounted aeration apparatus has a track extending between two distinct elevations that is coupled to a wall and bridge mount. An aeration unit is pivotally coupled to the track and has an aerator adapted to operatively at least partially submerge within and aerate a liquid. A selective mover or drive is adapted to operatively move the aeration unit along the track and thereby vary an elevation of the aeration unit. The universal wall and bridge mount supports the track and aeration unit. The universal wall and bridge mount has a first configuration for mounting to a structure such as a stationary bridge, and a second configuration for mounting to a wall. The universal wall and bridge mounted aeration apparatus may be adjusted to position the propeller after installation under the surface of the liquid through three axes of motion freedom.

Provided is an intelligent control-based dosing and stirring device for sediment pollution control, including a support underframe, a support frame, a chemical cartridge, and a stirring assembly which works through intelligent control. A support ring positioned in a middle position is fixed into the support underframe by multiple support rods, and an anti-shaking mechanism is arranged in the support ring, and mounted in the support ring by multiple shock-absorbing assemblies. The shock-absorbing assemblies are used for shock absorption, thus preventing the chemical cartridge from shaking. The anti-shaking mechanism includes a circular support block, and an annular groove is formed in the circular support block. The intelligent control-based dosing and stirring device for sediment pollution control relates to the technical field of dosing and stirring devices.