A bar blender comprises a blender blade driven by a motor (16) in a main housing (10). The handle (12) of the housing has a motor speed control button (14). A separate visual display on the housing shows the user the speed setting corresponding to the current position of the control button. The visual display is based on a mechanical linkage between the control button and the visual display to cause a display element to follow the button as it is moved by the user. This is provides a simple and reliable feedback to the user.

A bar blender comprises a blender blade driven by a motor (16) in a main housing (10). The handle (12) of the housing has a motor speed control button (14). A separate visual display on the housing shows the user the speed setting corresponding to the current position of the control button. The visual display is based on a mechanical linkage between the control button and the visual display to cause a display element to follow the button as it is moved by the user. This is provides a simple and reliable feedback to the user.

A cup structure includes a bottom, a body and a top cover. A bottom edge of the body is detachably sleeved at the bottom. The top cover is covered on a top of the body. The bottom includes a base, a driving assembly, a transmitting assembly and a cover. A top surface of the base is sunk inward and forms an accommodating space. The driving assembly is disposed in the accommodating space. The transmitting assembly is geared into the driving assembly. The cover is disposed on the transmitting assembly, wherein the cover includes a protrusion, a water-blocking layer and a mixer. The mixer is disposed on a top of the protrusion and includes at least one mixing blade. A power is transmitted to the mixer by the transmitting assembly after the power is generated by the driving assembly, so that the at least one mixing blade is rotated.

Proposed is a blender which is provided with a discharge system for removing static electricity. The blender includes a container body in which food is received, a main body provided under the container body and configured to support the container body, and a container lid mounted detachably to an upper surface of the container body and configured to open and close the upper surface of the container body, wherein the discharge system is provided in the main body so as to discharge static electricity generated in an inside or casing of the main body. Accordingly, the malfunction of the blender and the complaints of a consumer due to static electricity are prevented.

The invention provides an automatic and compact food preparation apparatus that prepares a food automatically. The food preparation apparatus of present invention is comprising of an electronic control unit that stores the recipes and accordingly controls the working of all the other units of the food preparation apparatus according to the recipe steps. The food preparation apparatus further includes a wok pan unit, a stirring unit, a raw ingredient dispensing—slot assembly unit and a spice or liquid dispensing unit that by working according to the recipe steps, cooks or prepares the food recipe. The food preparation apparatus further includes a user interface to allow user to select the recipe to prepare, to modify the recipe according to the user requirement and to communicate with the food preparation apparatus.

A vacuum blender according to the present invention comprises: a blender body including a container support case, an outer container seated in the container support case, a grinding blade, and a blade driving unit for rotating the grinding blade; an inner container unit including an inner container disposed in the outer container and in which the grinding blade is located, and an inner container driving unit for rotating the inner container; a vacuum unit installed in the container support case and configured to perform a blending operation on an object to be blended accommodated in the inner container in a vacuum state, wherein the outer container is opened and closed by means of an outer container cover, the inner container is opened and closed by means of an inner container cover, the inner container cover is assembled to rotate on the outer container cover.

A food processor (100) with a food preparation vessel (102), a base (104) housing a drive motor (111) and a spindle assembly (140) for detachable engagement with an accessory (109) for rotation in the preparation vessel (102). The spindle assembly (140) has a gear assembly such that the accessory (109) is driven at a speed that differs from that of the drive motor (111).

A kitchen device base having at least one collection area for at least one preparation module, whereby the collection area has at least one locking means for mechanical locking of the preparation module. A kitchen device base, a preparation module, and a kitchen device, with which automatic locking of various preparation modules on a kitchen device base is made possible, are realized in that the locking means has at least one drive unit and at least one movably mounted locking element, that the locking element can be moved at least indirectly by means of the drive unit, at least between a release position and a locking position, that in the release position the preparation module can be arranged in at least two different orientations in the collection area, and that in the locking position the preparation module is locked to the kitchen device base.

A drive assembly for a blender appliance includes an output drive shaft and an inner one-way bearing member received in an interior cavity of the output drive shaft. An outer bearing member is oppositely configured relative to the inner one-way bearing member and includes a receiving bore. The receiving well of the output drive shaft is received in the receiving bore of the outer one-way bearing member. An input drive shaft includes a first end received in a receiving bore of the inner one-way bearing member. A planetary gear system includes a sun gear that is operably coupled to the input drive shaft and gearingly engaged with a ring gear through a plurality of planet gears. A carrier member is operably coupled to the plurality of planet gears and includes a receiving bore in which the outer one-way bearing member is received for rotation therewith.

A micro puree machine includes a mixing shaft coupled to a blade and rotatable by means of a gear. A magnet is coupled to the gear and a rotation sensor is mounted on the machine housing. As the mixing shaft descends into the pre-frozen ingredients, the rotation sensor detects a magnetic field of the magnet as the gear rotates and generates a rotation signal in response. A controller receives the rotation signal and determines a rotation count associated with the gear, causing the mixing shaft to ascend back toward the housing once a pre-selected rotation count has been reached. The pre-selected rotation count correlates with the partial processing of the ingredients.