In some embodiments, the present disclosure provides a personalized cosmetic formula preparing system, a method of operating the system, and computer readable instructions for implementing the method. The system determines a personalized cosmetic formula for a consumer. In an embodiment, the determination is based on the consumer's preferences, lifestyle, and cosmetic attributes. The system comprises one or more beauty assessment devices, a digital hub in communication with the one or more beauty assessment devices, a dispenser, and a mixer. The system may be used directly in communication with the consumer, or may automatically obtain the formula from other sources. The companion app may control the constituent elements of the system remotely via the digital hub. The formula preparing system may cause a personalized cosmetic formula to be prepared and packaged without complex or expensive equipment and without extensive cosmetic technical training for the operator of the system.

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. The contact surface of said connecting flange has a radial extension such that mixing containers with different connection diameters on their mixing head connection 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.

A food mixing machine includes a mixer body including a column and a head extending from the column. A rotatable output member extends downward from the head for receiving a mixer tool. A bowl support is mounted for vertical movement along the column between a lowered position away from the head and a raised position toward the head. A drive assembly is linked to selectively drive the rotatable output member. A user interface, including a touch-screen display, is located on the mixer body. A controller is associated with the user interface, wherein the controller is configured to communicate mixing machine condition information via the touch-screen display.

A food mixing machine includes a mixer body including a column and a head extending from the column. A rotatable output member extends downward from the head for receiving a mixer tool. A bowl support is mounted for vertical movement along the column between a lowered position away from the head and a raised position toward the head. A drive assembly is linked to selectively drive the rotatable output member. A user interface, including a touch-screen display, is located on the mixer body. A controller is associated with the user interface, wherein the controller is configured to communicate mixing machine condition information via the touch-screen display.

A stand mixer appliance includes a casing that includes a base, a column mounted to the base, and a motor housing mounted to the column that extends outwardly above the base. A motor is positioned within the motor housing. The motor includes two pins. The motor housing includes a first portion and a second portion. The second portion includes both a hole and a slot. The slot is elongated along a transverse direction of the motor, and the two pins of the motor extend perpendicularly to the transverse direction. Each of the two pins of the motor are disposed within a respective one of the hole and the slot of the second portion of the motor housing.

An electrically controlled mixing and blending apparatus featuring high corrosion resistance and mixing efficiency includes a housing, a first bearing engaged to both sides of the housing, and the interior of both first bearings being coupled to a first rotating shaft, a second bearing engaged to a surface at the middle of the first rotating shaft and the interior of the second bearing being engaged to a surface of an output shaft of a first motor output shaft. Both sides of the first motor are fixedly coupled to a surface of the first rotating shaft through a first fixed rod. A gear drives the first motor, a blending rod and a stirring rack to swing in the front-rear direction through the first rotating shaft to increase the turbulence of the liquid raw materials, reduce the time required for mixing raw materials, and improve the production efficiency.

A stirring tool for a stirrer for stirring a mixture comprises a connecting element for connecting the stirring tool to a stirring drive, drivable about a rotational axis, of the stirrer, a carrier ring, a plurality of stirring spokes disposed between the connecting element and the carrier ring, and at least one stirring boss, which projects radially on the carrier ring, wherein two adjacent stirring spokes are arranged mutually offset in the direction of the rotational axis.

A machine for making liquid or semi-liquid food products is provided with a frame, a product processing unit and a control unit for driving the processing unit; the processing unit is in turn provided with a first vessel which is set in rotation about its central axis by a brushless gear motor and which defines inside it a product processing chamber, a stirrer provided with a spatula mounted inside the processing chamber, and a movement unit for moving the stirrer; the movement unit for moving the stirrer imparts to the spatula, through two distinct linear actuators, a first movement, towards and away from the bottom of the first vessel, and a second movement, independent of the first, towards and away from the inside wall of the first vessel.

Current cartridge-style mixers due not have the ability to measure mixing performance nor determine the need for maintenance based on performance. Risks of non-homogeneous mixing and insufficient maintenance can exist with cartridge-style mixers. A mixing system comprises a mixing apparatus, a first switch, a magnetic switch, and a controller. The mixing apparatus is configured to receive a cartridge and to mix a material. The mixing apparatus comprises a linear actuator configured to translate the cartridge or plunger in a vertical direction and a spindle configured to rotate a plunger. The first switch is configured to measure a number of strokes per unit of time of operating the linear actuator. The magnetic switch is configured to measure a speed of the spindle. The controller is configured to receive one or more mixing parameters, actuate the spindle and the linear actuator, and actuate a light to indicate if there was sufficient mixing.

Current cartridge-style mixers due not have the ability to measure mixing performance nor determine the need for maintenance based on performance. Risks of non-homogeneous mixing and insufficient maintenance can exist with cartridge-style mixers. A mixing system comprises a mixing apparatus, a first switch, a magnetic switch, and a controller. The mixing apparatus is configured to receive a cartridge and to mix a material. The mixing apparatus comprises a linear actuator configured to translate the cartridge or plunger in a vertical direction and a spindle configured to rotate a plunger. The first switch is configured to measure a number of strokes per unit of time of operating the linear actuator. The magnetic switch is configured to measure a speed of the spindle. The controller is configured to receive one or more mixing parameters, actuate the spindle and the linear actuator, and actuate a light to indicate if there was sufficient mixing.