An electric hand mixer comprises a housing having at least a bottom surface and a rear heel surface, a motor within the housing, one or more holes defined in the bottom surface for receiving a respective rotatable beater, and a power cord extending outward from the housing. A recess is defined in the housing. A first opening to the recess is defined in the bottom surface. A second opening to the recess is defined in the rear heel surface. The first and second openings are continuous with each other. The power cord extends outward from within the recess.

The present invention is directed to a hand-held modular kitchen multitool having a universal powerhead capable of being used with a variety of kitchen appliance attachments, such as a blender, a whisker, a wine opener, a can opener, and a spice grinder. A dual spice grinder attachment is also disclosed that can select one of two spices to grind. Also disclosed is a wine opener that automatically removes a cork from a bottle.

A micro puree machine including a housing, a power shaft, a bowl assembly and a platform. The power shaft extends from the housing. The bowl assembly including at least one locking bowl element. The platform includes at least one complementary locking platform element that is configured to engage the at least one locking bowl element such that rotation of the bowl assembly relative to the platform is prevented at times the bowl assembly is positioned thereon. The platform is rotatable from a first position to a second position relative to the housing such that the platform raises the bowl assembly towards the power shaft during the rotation of the bowl assembly and platform. The raising of the bowl assembly facilitates connection between the power shaft and a blade assembly that is positioned in a lid assembly on the bowl assembly.

A soft start circuit for a mixer is provided that includes an input for receiving an analog voltage representing a raw target speed; a current mirror for causing a speed target to change at a constant rate when the raw target speed represents a change from a current speed; and a comparator for receiving and comparing the raw target speed and an output from the current mirror and restricting the output from exceeding the raw target speed in order to restrict a soft start to only impede the speed target change when the raw target speed is increasing while not impeding the speed target change when the raw target speed is decreasing. The output of the soft start circuit is an analog representation of a soft start modified desired target speed.

A speed control assembly for an appliance includes a bracket. The bracket is aligned with a slot defined by an appliance body. A cam is slidably coupled with the bracket and has an engagement edge positioned at an angle relative to the bracket. A lever is operably coupled with the cam and extends through the slot. The lever is configured to move the cam along the bracket. A slider is fixedly coupled with the bracket. A magnet housing is operably coupled with the slider and is configured to house a magnet. The magnet housing defines a recess. A ball bearing is magnetically coupled with the magnet housing and is positioned within the recess. The ball bearing is configured to be selectively engaged with the engagement edge of the cam. A Hall-effect sensor configured to detect the position of the magnet.

The invention relates to a pull type transmission system, which comprises a pull mechanism. The pull mechanism at least comprises a coaxial column, the coaxial column is formed by connecting rotary discs with different diameters, and planes connecting the rotary discs with different diameters are connecting faces. The pull mechanism is provided with a rope tying position, the rope tying position is arranged on a side face of the pull mechanism, and the pull rope is connected to the pull mechanism through the rope tying position at one end and is wound around the rotary discs. The pull mechanism is connected to a resilience mechanism and is used for retracting the pull rope after the pull rope is pulled out. The invention provides a non-electric pull type transmission system. The corresponding rotating gears can be changed through simple up-down pulling actions without having to shut down and replace equipment or interrupt the pulling operation, making the use more convenient.

A blender having bi-directionally rotatable blades includes: a blade assembly including a main blade shaft that is provided to allow a first blade and a first main coupler to integrally rotate in a forward direction and a reverse-rotation blade shaft that is provided to allow a second blade and a first reverse-rotation coupler to integrally rotate in a reverse direction; and a gearbox assembly including a main gear shaft that is provided to allow a second main coupler and a main gear to rotate in the forward direction, at least one sub-gear that is engaged with the main gear and rotates in the reverse direction, a ring gear to which the sub-gear is internal and engaged, and a second reverse-rotation coupler that is configured to integrally rotate with the ring gear in the reverse direction and transmit the reverse rotation to the first reverse-rotation coupler.

A blender having bi-directionally rotatable blades includes: a blade assembly including a main blade shaft that is provided to allow a first blade and a first main coupler to integrally rotate in a forward direction and a reverse-rotation blade shaft that is provided to allow a second blade and a first reverse-rotation coupler to integrally rotate in a reverse direction; and a gearbox assembly including a main gear shaft that is provided to allow a second main coupler and a main gear to rotate in the forward direction, at least one sub-gear that is engaged with the main gear and rotates in the reverse direction, a ring gear to which the sub-gear is internal and engaged, and a second reverse-rotation coupler that is configured to integrally rotate with the ring gear in the reverse direction and transmit the reverse rotation to the first reverse-rotation coupler.

A food processing appliance includes a bowl to contain the food, with a side wall, a rotary work accessory arranged in the bowl, a lid arranged on the bowl, the lid including a manually-operated motor to cause a drive shaft to spin the work accessory around a rotation axis A by pulling on a cord transversely to the axis A.

The lid includes a first dynamic gasket arranged between the lid and the side wall to fill the space therebetween; a second dynamic gasket, arranged between the lid and the drive shaft to fill the space therebetween; each gasket having an inner wall, a connecting part arranged on the lid, an annular lip and a groove; the lip movable and deformable with a displacement angle α extending outwards relative to the axis A, so as to ensure a watertight seal when the lid is connected to the bowl.

A speed control assembly for an appliance includes a bracket. The bracket is aligned with a slot defined by an appliance body. A cam is slidably coupled with the bracket and has an engagement edge positioned at an angle relative to the bracket. A lever is operably coupled with the cam and extends through the slot. The lever is configured to move the cam along the bracket. A slider is fixedly coupled with the bracket. A magnet housing is operably coupled with the slider and is configured to house a magnet. The magnet housing defines a recess. A ball bearing is magnetically coupled with the magnet housing and is positioned within the recess. The ball bearing is configured to be selectively engaged with the engagement edge of the cam. A Hall-effect sensor configured to detect the position of the magnet.