A liquid mixing system includes a support housing at least partially bounding a compartment. A mount is secured to the support housing. A drive motor assembly is configured to engage a drive shaft for moving the drive shaft within the compartment of the support housing. A four bar linkage system extends between the mount and the drive motor assembly, the four bar linkage system being movable between a first position wherein the drive motor assembly is disposed at a first elevation and a second position wherein the drive motor assembly is disposed at a second elevation that is different from the first elevation.

A liquid mixing system includes a support housing at least partially bounding a compartment. A mount is secured to the support housing. A drive motor assembly is configured to engage a drive shaft for moving the drive shaft within the compartment of the support housing. A four bar linkage system extends between the mount and the drive motor assembly, the four bar linkage system being movable between a first position wherein the drive motor assembly is disposed at a first elevation and a second position wherein the drive motor assembly is disposed at a second elevation that is different from the first elevation.

A frozen food appliance and related method of making a frozen food product. A rotational drive assembly configured in an axial alignment using a direct drive to produce rotational movement of a blade element to contact a frozen food precursor in a frozen food container associated with the frozen food appliance where the rotational drive assembly omits rotational speed modifying gears and transmissions positioned between a drive motor and the blade element. In another aspect, a rotational drive assembly may be kept in axial alignment with a frozen food container via a multi portioned container mount having a float connector.

A liquid mixing system includes a support housing at least partially bounding a compartment. A mount is secured to the support housing. A drive motor assembly is configured to engage a drive shaft for moving the drive shaft within the compartment of the support housing. A four bar linkage system extends between the mount and the drive motor assembly, the four bar linkage system being movable between a first position wherein the drive motor assembly is disposed at a first elevation and a second position wherein the drive motor assembly is disposed at a second elevation that is different from the first elevation.

A liquid mixing system includes a support housing at least partially bounding a compartment. A mount is secured to the support housing. A drive motor assembly is configured to engage a drive shaft for moving the drive shaft within the compartment of the support housing. A four bar linkage system extends between the mount and the drive motor assembly, the four bar linkage system being movable between a first position wherein the drive motor assembly is disposed at a first elevation and a second position wherein the drive motor assembly is disposed at a second elevation that is different from the first elevation.

A frozen food appliance and related method of making a frozen food product. A rotational drive assembly configured in an axial alignment using a direct drive to produce rotational movement of a blade element to contact a frozen food precursor in a frozen food container associated with the frozen food appliance where the rotational drive assembly omits rotational speed modifying gears and transmissions positioned between a drive motor and the blade element. In another aspect, a rotational drive assembly may be kept in axial alignment with a frozen food container via a multi portioned container mount having a float connector.

A tube management system includes an elongated rack extending between a first end and an opposing second end; an elongated first shaft having a first end and an opposing second end, the first shaft being secured to the rack; a securing structure secured to the first shaft; a collapsible bag bounding a chamber; and a tubular member projecting from the collapsible bag, wherein the securing structure at least partially encircles the tubular member.

A tube management system includes an elongated rack extending between a first end and an opposing second end; an elongated first shaft having a first end and an opposing second end, the first shaft being secured to the rack; a securing structure secured to the first shaft; a collapsible bag bounding a chamber; and a tubular member projecting from the collapsible bag, wherein the securing structure at least partially encircles the tubular member.

The invention relates to a method (100) for congruent alignment of a first polygonal multi-edge geometry (2) of a rotor shaft (3) of a dynamic mixer (4) with a second polygonal multi-edge geometry (5) of a drive shaft (6) of a motor (7) of a mixing apparatus (8), and optionally insertion of the second polygonal multi-edge geometry (5) of the drive shaft (6) of the motor (7) of the mixing apparatus (8) into or onto the first polygonal multi-edge geometry (2) of the rotor shaft (3) of the dynamic mixer (4), as well as a dynamic mixer for use in the method as also use of the mixer in the method.

The invention relates to a method (100) for congruent alignment of a first polygonal multi-edge geometry (2) of a rotor shaft (3) of a dynamic mixer (4) with a second polygonal multi-edge geometry (5) of a drive shaft (6) of a motor (7) of a mixing apparatus (8), and optionally insertion of the second polygonal multi-edge geometry (5) of the drive shaft (6) of the motor (7) of the mixing apparatus (8) into or onto the first polygonal multi-edge geometry (2) of the rotor shaft (3) of the dynamic mixer (4), as well as a dynamic mixer for use in the method as also use of the mixer in the method.