The disclosure discloses a bevel planetary gear mechanism applied to a stand mixer, including a center bevel gear (2), a first bevel planetary gear (10), a second bevel planetary gear (3), a third bevel planetary gear (4), an internal bevel gear (5) and a bevel planetary gear bracket (11), wherein, the center bevel gear (2) is mounted on a spindle (1); the first bevel planetary gear (10), the second bevel planetary gear (3) and the third bevel planetary gear (4) are all engaged with the center bevel gear (2); the internal bevel gear (5) surrounds the first bevel planetary gear (10), the second bevel planetary gear (3) and the third bevel planetary gear (4) and are engaged with such three gears. By using the bevel planetary gear mechanism provided by the disclosure, the stand mixer has a pitched kneading hook, thereby improving the kneading effect of the stand mixer.

A product preparation system and method wherein a single-use product container assembly and a multiple motion intelligent driving device are employed to process contents of the container assembly.

A mixing machine includes a mixing head and at least one connection means for connecting a mixing container containing material to be mixed to said mixing head for forming a closed mixing container. The mixing head, as part of a pivotable assembly, is pivotably mounted with respect to a frame such that the closed mixing container formed from the mixing head and the mixing container can be pivoted relative to the frame for performing the mixing process. The mixing head carries at least one rotationally-driven mixing tool. The mixing head comprises a head plate having a connecting flange molded thereon which is configured as an annular disc and comprises a planar contact surface. At least two ring seals of differing diameters are arranged in said contact surface of the connecting flange at a spacing between each other, such that mixing containers with different connection diameters of their mixing head side can be connected to said mixing head. The at least one connection means is configured for gripping mixing containers which differ in the diameter of their connection sides.

The present disclosure relates to a foldable stirring cutter, to resolve technical problems that a fixed blade structure of a current stirring cutter is easy to be damaged in use by a lever force generated after collision with a stirred material, and is easy to be jammed by a large heterogeneous stirred material. The foldable stirring cutter includes a base having a cutter assembly rotationally disposed at a top. The cutter assembly includes a bearing component that is detachably disposed on an outer edge surface and a shaft. The bearing component includes a bearing plate and at least two extension plates that are fastened to an outer edge surface of the bearing plate in a ring-shaped equidistant array. Two sets of force-controlled cutter components that are movably connected to the extension plates are disposed on the bearing component. Connection holes are provided inside the extension plates, and movable connection assemblies that are used to movably connect the force-controlled cutter components to the extension plates are disposed inside the connection holes. The force-controlled cutter components deflect and unfold around axes of the movable connection assemblies under action of a centrifugal force. The present disclosure has the advantage of reducing damage to the cutter and preventing the cutter from being jammed by the stirred material.

The present disclosure relates to a foldable stirring cutter, to resolve technical problems that a fixed blade structure of a current stirring cutter is easy to be damaged in use by a lever force generated after collision with a stirred material, and is easy to be jammed by a large heterogeneous stirred material. The foldable stirring cutter includes a base having a cutter assembly rotationally disposed at a top. The cutter assembly includes a bearing component that is detachably disposed on an outer edge surface and a shaft. The bearing component includes a bearing plate and at least two extension plates that are fastened to an outer edge surface of the bearing plate in a ring-shaped equidistant array. Two sets of force-controlled cutter components that are movably connected to the extension plates are disposed on the bearing component. Connection holes are provided inside the extension plates, and movable connection assemblies that are used to movably connect the force-controlled cutter components to the extension plates are disposed inside the connection holes. The force-controlled cutter components deflect and unfold around axes of the movable connection assemblies under action of a centrifugal force. The present disclosure has the advantage of reducing damage to the cutter and preventing the cutter from being jammed by the stirred material.

A blending apparatus includes a blending jar and a lid. The blending jar has an internal surface defining an internal volume, and a mixing blade positioned within the internal volume. The lid is releasably mounted to the blending jar and includes at least one scraper extending into the internal volume. The at least one scraper is adjacent to the internal surface of the blending jar and is arranged and configured to disrupt rotational flow of food particles within the internal volume and/or scrape food particles from an inner surface of the blending jar.

A capsule for mixing substances includes a chamber having first and second ends. A piston is fitted in the chamber. The piston has a proximal end facing the first end, and a distal end facing the second end. A mixer element is arranged within the chamber between the piston and the second end. The mixer element is disposed at a distal end of a mixer rod. The piston has an aperture through which the mixer rod passes. The piston and mixer element are separately displaceable relative to the first and second ends and relative to each other. The piston includes a plurality of cavities within the piston, such that one cavity is separated from another cavity and filled with a different ingredient substance.

A capsule for mixing substances includes a chamber having first and second ends. A piston is fitted in the chamber. The piston has a proximal end facing the first end, and a distal end facing the second end. A mixer element is arranged within the chamber between the piston and the second end. The mixer element is disposed at a distal end of a mixer rod. The piston has an aperture through which the mixer rod passes. The piston and mixer element are separately displaceable relative to the first and second ends and relative to each other. The piston includes a plurality of cavities within the piston, such that one cavity is separated from another cavity and filled with a different ingredient substance.

A household mixer appliance having a mixing container with an inner surface and an open top, a drive arrangement and a hook. The hook has a sole attachment portion which, when attached to the drive arrangement, abuts a first inner surface portion of the mixing container inner surface. The sole attachment portion is attachable to the drive arrangement via a through hole in the first inner surface portion such that the hook is rotatable around a substantially horizontal axis of rotation within the mixing container when the hook is attached to the drive arrangement.

A stirring paddle for isothermal titration calorimetry includes a blade secured to one end of a shaft. The blade has an edge and a pair of opposing surfaces. A lip extends from the edge and forms a non-zero angle with respect to the opposing surfaces. In some embodiments, the blade has a twisted rectangular shape defined by a pair of first opposing edges and a pair of second opposing edges. One of the first opposing edges is oriented at a rotation angle with respect to the shaft axis that is different than an orientation of the other first opposing edge with respect to the shaft axis. Advantageously, the stirring paddle achieves improved turbulent mixing of injections into liquid within a sample cell, resulting in shorter measurement times. The improved mixing efficiency allows the stirring paddle to be operated at a lower rotation rate.