A vertical household noodle maker includes a base, a stirring container connected to the base, a stirring rod longitudinally arranged in the stirring container, an extrusion cylinder horizontally arranged at one side below the stirring container, a spiral rod arranged in the extrusion cylinder, an extrusion die and a control unit. The stirring rod includes a rod body and a stirring blade. The motor rotates the stirring rod and the spiral rod, and a feeding inlet in communication with the extrusion cylinder is provided at a bottom of the stirring container. An inner wall of the stirring container is provided with a cutting rod, and a projection of the cutting rod at least partially overlaps with a projection of the stirring blade in the horizontal direction when the stirring blade is driven by the motor to rotate to a position of the cutting rod.

A vertical household noodle maker includes a base, a stirring container connected to the base, a stirring rod longitudinally arranged in the stirring container, an extrusion cylinder horizontally arranged at one side below the stirring container, a spiral rod arranged in the extrusion cylinder, an extrusion die and a control unit. The stirring rod includes a rod body and a stirring blade. The motor rotates the stirring rod and the spiral rod, and a feeding inlet in communication with the extrusion cylinder is provided at a bottom of the stirring container. An inner wall of the stirring container is provided with a cutting rod, and a projection of the cutting rod at least partially overlaps with a projection of the stirring blade in the horizontal direction when the stirring blade is driven by the motor to rotate to a position of the cutting rod.

Various examples are related to making flatbreads such as, e.g., a compact machine for making flatbread in a residential kitchen-type environment or other countertop, tabletop, or space limited applications. In one example, a machine includes a hopper including a mixing chamber configured for bulk addition of raw materials for preparation of flatbread pieces; a mixing assembly configured to blend the raw materials into a flatbread dough mixture; a dough piecing assembly configured to generate a dough piece from an extruded portion of the flatbread dough mixture; a lower platen configured to transfer the pressed flatbread dough piece to a cooking zone on the dough contacting surface for cooking; and a flatbread ejection station configured to remove a cooked flatbread piece from the machine. A second cooking zone can be included to further cook the pressed flatbread dough piece prior to ejection from the machine.

A mixing machine includes a head extending over a bowl receiving location, the head including a downwardly extending rotatable output shaft for receiving a mixer tool, the head including a planetary system therewithin for effecting rotation of the rotatable output shaft about its axis and orbiting of the shaft axis about another axis. A motor includes an output operatively connected to drive the planetary system. A control system includes a plurality of sensors, each sensor located for detecting a respective condition of mixing machine, and a diagnostic control operable to (i) track outputs from the plurality of sensors over time, (ii) analyze the tracked outputs and (iii) produce an alert indication based upon the diagnostic control identifying a performance characteristic indicative of a need for service or repair of the mixing machine.

A mixing machine includes a head extending over a bowl receiving location, the head including a downwardly extending rotatable output shaft for receiving a mixer tool, the head including a planetary system therewithin for effecting rotation of the rotatable output shaft about its axis and orbiting of the shaft axis about another axis. A motor includes an output operatively connected to drive the planetary system. A control system includes a plurality of sensors, each sensor located for detecting a respective condition of mixing machine, and a diagnostic control operable to (i) track outputs from the plurality of sensors over time, (ii) analyze the tracked outputs and (iii) produce an alert indication based upon the diagnostic control identifying a performance characteristic indicative of a need for service or repair of the mixing machine.

A mixing machine includes a head extending over a bowl receiving location, a rotatable output shaft for receiving a mixer tool, and a gear system for effecting rotation of the rotatable output shaft about its axis and orbiting of the shaft axis about another axis. An electric motor includes an output operatively connected to drive the gear system. A variable frequency drive is connected to deliver 3-phase power to the electric motor to achieve variable speed and torque. The variable frequency drive includes a plurality of embedded sensors, including embedded current sensors and embedded voltage sensors. A diagnostic control is configured and operable to analyze outputs from the embedded sensors and produce an alert indication upon identification of a characteristic indicative of at least one of input power brownout, input power surge, machine short circuit, motor phase insulation arch, motor phase to ground arch or motor loss of phase.

A mixing machine includes a head extending over a bowl receiving location, a rotatable output shaft for receiving a mixer tool, and a gear system for effecting rotation of the rotatable output shaft about its axis and orbiting of the shaft axis about another axis. An electric motor includes an output operatively connected to drive the gear system. A variable frequency drive is connected to deliver 3-phase power to the electric motor to achieve variable speed and torque. The variable frequency drive includes a plurality of embedded sensors, including embedded current sensors and embedded voltage sensors. A diagnostic control is configured and operable to analyze outputs from the embedded sensors and produce an alert indication upon identification of a characteristic indicative of at least one of input power brownout, input power surge, machine short circuit, motor phase insulation arch, motor phase to ground arch or motor loss of phase.

A kneading device 1 comprising an inner cone 2 and an outer cone 3, wherein the inner cone 2 and the outer cone 3 defines a space 4 in between the inner cone and the outer cone; from a horizontal plane the inner cone 2 inclines and forms an angle ic; from the same horizontal plane the outer cone 3 inclines and forms an angle oc; where the inner cone 2 has an opening in a bottom of the inner cone 2; where both the inner cone 2 and the outer cone 3 continue vertically in an inner extension 5 and an outer extension 6, respectively, wherein a space in between the inner extension 5 and the outer extension 6 is a gap E; where scraping wings 7 extend from a center portion 8 of the kneading device 1 and through the inner cone 2 and the outer cone 3 and towards, but not fixated to, an inner wall 9 of the outer cone 3; and where the outer cone 3 inclines more than the inner cone 2, when viewed from the horizontal plane, so that angle oc>angle ic.

A kneading device 1 comprising an inner cone 2 and an outer cone 3, wherein the inner cone 2 and the outer cone 3 defines a space 4 in between the inner cone and the outer cone; from a horizontal plane the inner cone 2 inclines and forms an angle ic; from the same horizontal plane the outer cone 3 inclines and forms an angle oc; where the inner cone 2 has an opening in a bottom of the inner cone 2; where both the inner cone 2 and the outer cone 3 continue vertically in an inner extension 5 and an outer extension 6, respectively, wherein a space in between the inner extension 5 and the outer extension 6 is a gap E; where scraping wings 7 extend from a center portion 8 of the kneading device 1 and through the inner cone 2 and the outer cone 3 and towards, but not fixated to, an inner wall 9 of the outer cone 3; and where the outer cone 3 inclines more than the inner cone 2, when viewed from the horizontal plane, so that angle oc>angle ic.

A kitchen appliance (100) is disclosed comprising a compartment (110) for receiving flour, said compartment comprising a sensor (120) for producing a sensor reading indicative of a dielectric property of said flour or a product comprising said flour. The kitchen appliance further comprises a processing arrangement (130) communicatively coupled to the sensor for determining an initial moisture content of said flour or product from said sensor reading and adapted to generate a control signal indicative of an amount of water to be added to the compartment as a function of the determined moisture content. A method of controlling a flour product-based food preparation process is also disclosed.