Provided is a food processor and an attachment for a food processor. The attachment having a substantially S-shaped vertical rotational member having an upper end and a lower end, the lower end of the rotational member configured for secure engagement to a base motor. There is also a first blade assembly attached to a lower portion of the rotational member, the first blade assembly having at least one upward-angled blade, and a second blade assembly attached to an upper portion of the rotational member, the second blade assembly having at least one downward-angled blade. The first blade assembly and second blade assembly are disposed along the rotational member such that the first blade assembly and second blade assembly offset one another along the height and width of the housing.

A food processor includes a base, a motor disposed within the base, a drive shaft operatively connected to the motor and extending outwardly from the base, the output shaft being rotatable upon actuation of the motor, a bowl removably coupled to the base, a lid removably coupled to the bowl so as to define a processing chamber, a slicing assembly positioned within the processing chamber and driven by the motor, the slicing assembly being positionable in a plurality of slicing positions to produce sliced food items of varying thicknesses, and a slice thickness adjustment mechanism operable to move the slicing assembly between the plurality of slicing positions. The slice thickness adjustment mechanism includes a cartridge mounted to the bowl, the cartridge including an actuator drivingly coupled to a drive screw. Rotation of the drive screw causes the slicing assembly to move between the plurality of slicing positions.

The present application relates to an apparatus for processing a food stuff. The apparatus has a housing (2), and a cutting tool (5) rotatably mounted in the housing (2) having a cutting edge (35) and a trailing edge (31). The cutting tool (5) is arranged to pass once per revolution through a processing region (43) in the housing in which a food stuff is receivable, and to pass through a recovery region (45). The recovery region is defined in the housing between the trailing edge passing from the processing region and the cutting edge passing into the processing region as the cutting tool rotates, and the cutting tool is free to rotate in the processing region without contacting the food stuff. Therefore, the cutting tool (5) acts on a food stuff as the cutting tool rotates through the processing region, and recovers the rotational speed lost due to acting on a food stuff in the processing region as the cutting tool (5) rotates through the recovery region. The present application also relates to a food processor and to a method of processing a food stuff.

Provided is a bidirectional simultaneous rotary blade bundle for a mixer, the bidirectional simultaneous rotary blade bundle comprising: a housing (110); a forward rotary shaft (120) installed on the housing (110); a forward rotation blade (K1) provided on the forward rotary shaft (120); a central gear (130) axially installed on the forward rotary shaft (120); horizontal insertion gears (141, 142, and 143) engaged with the central gear (130); a reverse rotor (160), of which inner gear teeth (164) are engaged with and rotate on the outside of the horizontal insertion gears (141, 142, and 143); and a reverse rotation blade (K2) installed on the reverse rotor (160), wherein the horizontal insertion gears (141, 142, and 143) are rotated in the reverse direction according to the forward rotation of the central gear (130) such that the inner gear teeth (164) are rotated in the reverse direction.

The invention described herein is directed to an inline spiral cutting food processor that includes a motor that rotates an upper positioned disc with a blade assembly by means of a belt or gear assembly or mechanism. The entrance and exit chute are fixed and positioned in-line with the axis of rotation of the blade supporting disc member. The entrance chute is positioned above the cutting disc, and the exit opening (or chute) is below. During operation a food item is pushed down the entrance chute as the blade rotates and cuts it. Cut food falls down through the opening or exit chute into a storage container or jar. The food cutting assembly is configured to generate spiral or helical food from vegetables.

A blender includes a container body in which food is accommodated, a main body provided underneath the container body and supporting the container body, a container lid detachably mounted on an upper surface of the container body and opening and closing the top of the container body, and a blade assembly of which a blade chops the food inside the container body into small pieces. At least one end portion of the main blade is formed in such a manner as to have a smaller thickness than a center portion thereof.

A food processing system includes a food processing base, an attachment configurable with said food processing base, said attachment including a processing chamber, a heat distribution element for transferring heat to a fluid within said processing chamber, and a controller associated with the system. The controller is programmable to evaluate a plurality of successive changes in temperature of said heat distribution element, and a value of each temperature change between each of said plurality of successive changes in temperature to determine if a fluid temperature in said processing chamber is equal to a target temperature.

A blender includes a container body in which food is accommodated, a main body provided underneath the container body and supporting the container body, a container lid detachably mounted on an upper surface of the container body and opening and closing the top of the container body, and a detection system detecting whether or not the container lid is mounted on the container body. A seating support is formed on an upper surface of the main body in a manner that protrudes upward therefrom to be stepped, and a bottom surface of the container body being seated on the seating support.

A blender which an electrical signal via a transparent film so as to detect whether a container lid is closed. The blender includes a container body receiving food; a main body provided under the container body and supporting the container body; a container lid mounted removably to the upper surface of the container body and configured to open/close the upper part of the container body; and a detection system configured to detect whether the container lid is mounted to the container body, wherein the detection system includes a transparent electrode film attached to the surface of the container body and guiding the flow of electricity. Accordingly, the transparent electrode film can transmit whether the container lid is mounted to the main body without spoiling the appearance of the container body made of a transparent material.

A machine (1) for stirring a liquid food substance has: a container (10) delimiting a cavity (11) with a bottom (12) and a peripheral wall (13) for containing the liquid food substance to be stirred; an impeller (20) comprising an impelling member (21) which is configured to be rotated in the cavity (11), the impeller (20) including an arrangement of driven magnetic elements (26) in the form of permanent magnets; and a motor (30) having an output shaft (31) that is magnetically coupled to the impelling member (21) via the container bottom (12) and/or peripheral wall (13) for driving the impelling member (21), the output shaft (31) driving an arrangement of driving magnetic elements (36,36′) that cooperate magnetically with the driven magnetic elements (26) so as to drive the impeller (20) in rotation. One of the driven magnetic elements (26) is positioned to: generally face a first driving magnetic element (36) in a generally attraction orientation relative to said one driven magnetic element (26), the first driving magnetic element (36) driving this one driven magnetic element (26) in rotation; and be off-set relative to a second driving magnetic element (36′) in a generally repulsion orientation relative to the one driven magnetic element (26), the second magnetic element (36′) driving the one driven magnetic element (26) in rotation.