The present invention relates to a double-screen grinding mechanism and a double-screen grinding juicer, belonging to the technical field of household appliances. The juicer comprises a motor box, a motor, a middle cover, a grinding mechanism and an upper cover, wherein the grinding mechanism consists of a filter screen and a rotor, the filter screen being of a double-layer filter screen structure and comprising an upper filter screen and a lower filter screen, the rotor comprising an upper rough-grinding portion and a lower fine-grinding portion; the motor is mounted in the motor box; the middle cover is fixed on the motor box; the filter screen is mounted within the middle cover; the rotor is located in the filter screen; the upper cover is covered on the middle cover to shield the filter screen and the rotor; and, the rotor is connected to the motor via a rotor shaft.

A juice extraction module for a juicer is provided, which includes a container formed with a juice discharge port, a sieve positioned inside of the container, a screw positioned inside of the sieve to extract juice from a material, and a lid coupled to a top end of the container and formed with a input port through which the material is input. The juice extraction module includes a crushing portion formed on a top end of the screw to be narrowed upward, the crushing portion having a crushing blade formed thereon; and a crushing processing portion connected to the input port and formed in a bottom of the lid to be concave for accommodating the crushing portion.

A juice extractor (100) is disclosed comprising a food processing chamber (110) including a food inlet (130), a juice outlet (140) and a pulp outlet (150), wherein the food processing chamber comprises a food entry section (112) including the food inlet and the juice outlet; and a food compression section (114) extending between the food entry section and the food pulp outlet; a spindle (120) extending through the food processing chamber for transporting food from the food entry section through the food compression section, said spindle comprising a body (122) and a helical member (123) extending from said body by a height (H) of no more than 10 mm, said helical member including a helical cutting portion (124) in the food entry section; and a motor (160) including a gear box coupled to said spindle and adapted to rotate the spindle at a rotation speed of at least 300 rotations per minute during operation of the juice extractor.

A slow juicer is disclosed including a base having a motor for turning a shaft, a chamber for detachably mounting to the base, a strainer positioned within the chamber, an auger positioned within the strainer and coupled to the shaft, a detachable cover for the chamber, the cover having a hopper positioned atop a feed tube extending from the cover, and a pusher configured to fit within the feed tube, wherein the hopper is sloped toward the feed tube.

The present technology provides a device, such as a food processor with interchangeable components to allow the device to serve as a juicer, pasta maker, slicer, grinder, and frozen dessert maker. The device driver receives components that attach to the outlet of the device driver via a screwed connection or other suitable connection. The device drives a central shaft connected to interchangeable components that mix pasta ingredients, drive an extrusion auger, drive a rotating slicer, or perform any other suitable functions. The components may extrude pasta, juiced pulp, frozen desserts, or ground meat. The components may receive food products and auger the food products via a tube or cylinder via a helical screwed surface of the auger. Other components drive a food slicer or a meat grinder. By changing the components connected to the drive motor of the device, five different food processing functions may be utilized.

The present disclosure provides a squeezing threaded rod, a squeezing component and a food processor. The squeezing threaded rod includes: a rod body, and the rod body includes a feeding segment, a squeezing segment connected with the feeding segment and a residue discharge segment connected with the squeezing segment; and the area of the cross section of the rod body gradually increases from the feeding segment to the squeezing segment. In the squeezing threaded rod provided by the embodiments of the present disclosure, the stress direction of juice squeezing and residue discharge thereof is consistent with the thrust direction of the rod body, in this case, the juice squeezing force and the residue discharge force can be increased, the food residues at a residue discharge opening can be discharged more easily, then the phenomenon that the food residues block the residue discharge opening can be reduced.

A masticating juicer includes an auger configured to rotate within a drum to perform a masticating process with respect to at least one food item introduced into the masticating juicer with the masticating process producing a juice and a pulp. An end cap is coupled to an end of the drum and is adjustable relative to the drum with respect to an axial direction of the auger. The end cap includes a flexible ring disposed adjacent an end of the auger formed from a resiliently flexible material configured to flex in reaction to the pulp applying pressure to the flexible ring. The flexing of the flexible ring increases a cross-sectional flow area between the auger and the flexible ring to accommodate a back pressure generated by the pulp.

Disclosed is a juicer device. In some aspects, the juicer includes a feed housing releasably connected about a rotatable cutter, and an input chute of the feed housing can be offset away from a side of the cutter that rotates upward. In some aspects, the juicer includes a feed housing releasably connectable by a rotation of the feed housing relative to the mount from an aligned position to an installed position so that the feed housing is locked in place in response to the rotating motion. In some aspects, the juicer includes a press chamber in which pulp can be squeezed for juice extraction. The press chamber can include a base and a wall, and a press chamber form can include a continuous piece of material forming at least a portion of the base, at least a portion of the wall, and a transition between the base and the wall.

An oil extractor that includes: a main body housing; a motor; a feed hopper detachably coupled to the upper end of the main body housing to feed grain; a shell that communicates with the lower end of the feed hopper to receive the grain and is detachably coupled to one side of the main body housing; a screw shaft inserted into the shell and having an end portion that passes through one side of the main body housing and is coupled to the motor; a fastening means for detachably coupling the shell to the main body housing; and a shell cover surrounding the shell. The shell cover has a groove formed on its lower portion for receiving the shell and is supported by the main body housing and moves between a first position at which the shell is covered and a second position at which the shell is exposed.

A juicer for juicing produce can have a first juicing gear. The first juicing gear can include a first main body. The first main body can be configured to rotate in a first direction. The main body can have a plurality of first teeth. The first teeth can include a first top surface with a first exposed cavity. The first exposed cavity can be formed on the first top surface of the first teeth. The first exposed cavity can include a first leading edge. The first leading edge can be configured bite the portion of the produce from a remainder of the produce, as the juicing gear rotates in the first direction. The first teeth can be configured to crush the portion of the produce and/or the remainder of the produce, as the juicing gear rotates in the first direction, thereby releasing juice from the produce.