A bowl assembly for a stand mixer includes a bowl with a skirt mounted to a lower end of the bowl. A plurality of radially-outwardly projecting nubs are mounted on the skirt and engage the stand mixer. The bowl assembly nubs may be spring-loaded and biased toward a radially-outward extended position.

Food processing apparatuses having a drive unit which has more than one mode of operation, works with more than one food processing container, and/or may be operated in more than orientation are disclosed. The drive unit may be operated in first and second modes of operation. In some embodiments, the drive unit may be actuated in a different manner in the second mode of operation as compared to the first mode of operation. In some embodiments, the orientation of the drive unit in the second mode of operation is vertically flipped upside-down as compared to the orientation of the drive unit in the first mode of operation.

The invention relates to a food processing device (100), comprising: a jar (10), a base unit (20), a vacuum mechanism (30) for sucking air from the jar (10), comprising a vacuum pump (31) arranged in the base unit (20) and a first vacuum conduit (32) extending through the base unit (20), and a lid (40) for covering the jar (10) and realizing air communication between the jar (10) and the base unit (20), wherein the vacuum mechanism (30) further comprises a second vacuum conduit (33) extending through the lid (40), wherein the respective vacuum conduits (32, 33) are engageable to each other through respective engaging ends (34, 35) thereof, and wherein at least one of the engaging ends (34, 35) of the respective vacuum conduits (32, 33) is displaceable between an outward position and a retracted position in the respective one of the base unit (20) and the lid (40).

A blender jar assembly comprises a container portion having an open end for receiving the foodstuff to be blended and for dispensing the foodstuff after blending and a base portion selectively coupled to the container portion. The base portion comprises a floor and a sidewall connected to and extending from the floor to form a chamber for receiving at least a portion of the foodstuff during a blending operation. The chamber has an open end in fluid communication with the open end of the container portion when the container portion and the base portion are selectively coupled. The base further comprises one or more rotatable blades that are fully contained within the chamber formed by the floor and the sidewall and do not extend beyond a rim of the sidewall.

A blending system is shown and described herein. The blending system may include a base including a motor, a blade assembly selectively and operably engaged with the base, where the motor drives the blade assembly, and a container having a cavity. The container includes a flute protruding from an inner surface. An exaggerated flute may extend closer to the blade assembly than the flute.

A food preparation appliance has a base, a blade member rotatable in a direction of rotation, and a container with a closed bottom, an open top and a tubular sidewall together defining an interior space of the container. The top of the container is configured for releasable connection with the base, with the blade member disposed within the interior space of the container. The sidewall has a rib projecting inward of the interior space of the container and extending lengthwise along at least a portion of the sidewall from the top of the container toward the bottom of the container. The rib has, in the direction of rotation of the blade member, a peak defined as the shortest transverse dimension measured from the center of the container to the sidewall at a respective height along the portion of the sidewall having the rib, the rib being asymmetric in transverse cross-section.

The present disclosure provides a food processor including an electronic scale (2) and a machine (1) placed on the electronic scale (2). The electronic scale (2) includes an electronic scale printed circuit board (3), an insulating plate (4), a sensor fixing plate (5), four weight sensors (6) fixed on the sensor fixing plate (5), and a sensor fixing base (7) configured to be placed on a working platform surface for the food processor. A ground wire (8) is connected to the sensor fixing plate (5) to ground outer shells of the four weight sensors (6) simultaneously, so that interference introduced from the machine (1) or from outside is filtered out through the ground wire (8) when the electronic scale (2) is in operation.

A blending system is provided for identifying a blending container. The blending system may include an attachment member that attaches to a blending container. The attachment member may include an identification tag. A receiving system may communicate with the identification tag to identify the container. The receiving system may measure characteristics of the blending container. The characteristics can be compared to stored characteristics.

A beverage container for a blender includes one or more vibrating mechanisms coupled to a bottom portion of the beverage container or integrated within one or more walls of the beverage container. After a beverage has been blended, the one or more vibrating mechanisms are activated as the beverage is being poured. Vibrations from the one or more vibrating mechanisms are mechanically transmitted to the beverage container, thereby promoting the pourability of the beverage from the beverage container, including dislodging ingredients in the beverage that became lodged or trapped in crevices of the beverage container during the prior blending process, and freeing up beverage ingredients that accumulated at the bottom of the beverage container during the prior blending process.

A blender or food processor having electronics associated therewith including at least one controller, at least one current sensor and at least one speed sensor, the controller controls the operation of the blender motor based upon the contents being blended inside the blender jar and compares measured current and speed values and measured changes in the current and speed values to predetermined values stored in memory in order to (1) determine the load size placed in the blender jar, (2) determine if cavitation exists in the blender jar, and (3) determine the final consistency associated with the output of the product placed within the blender jar as selected by the user.