The present disclosure provides a food processor including: a host component, wherein the host component includes a driving component; a barrel body component mounted on the host component and including: a feed inlet, a first barrel body communicated with the feed inlet, a second barrel body communicated with the first barrel body through a communication opening, a crushing device arranged in the first barrel body, connected to the driving component and rotating under the driving of the driving component, and an extrusion device arranged within the second barrel body, connected to the driving component and rotating under the driving of the driving component; wherein the crushing device can operate with an inner side wall of the first barrel body so as to crush food entering the first barrel body, and the crushed food enters the second barrel body through the communication opening under the action of the crushing device.

A blender system includes a base and a steamer basket. The basket is inserted into a container. The container has interior pillars. The basket contacts and rests on the pillars. The pillars keep the basket above blades disposed in the container. The basket receives foodstuff. The base includes a motor and a housing. The container is attached to the housing. The motor drives the blades to interact with contents within the container.

A dual function garlic press includes an upper handle having a plunger, a lower handle having a receiving chamber and a cutter grid. The cutter grid is pivotally connected to the first side of plunger. The upper handle is rotatable in relation to the lower handle about a vertical axis between a first position where the first side of the plunger faces towards the receiving chamber when the upper handle and the lower handle are at the close position, and a second position where the second side of the plunger is juxtaposed to the bottom of the receiving chamber when the upper handle and the lower handle are at the close position to crush the item in the receiving chamber.

A foodstuff sieve station includes a hopper to pour floury foodstuff and an electrically-operated sifting assembly to sift it for separating impurities from still-usable foodstuff. The sifting assembly includes a hopper-shaped with bell-shaped, rotatable sieve housed/recessed inside the casing. The sieve has-an axis tilted with respect to the vertical and an upward mouth underneath an outlet of the hopper to receive foodstuff therefrom. An electric motor assembly rotates the sieve about the axis. The sieve prevents the foodstuff having a grain size higher that a threshold value to flow through, and has an inwardly protruding assembly that projects from the inner surface and extends on a helical-shaped path from the bottom of the sieve to the mouth of the sieve.

A screw-rod squeeze juicer includes a base having a motor, a crushing chamber mounted on the base, and a screw rod arranged inside the crushing chamber. The crushing chamber includes a crushing chamber body, the crushing chamber body has a juice outlet and a residue outlet, the crushing chamber has a feeding opening and a feeding channel connected to the feeding opening, the feeding channel includes an upper opening and a lower opening connected to the feeding opening. A rotatable overturn storage container is provided at the upper opening, a rotation center of the overturn storage container traverses the upper opening, and the overturn storage container is configured for placing a material and is rotatable about the rotation center in any direction.

A screw-rod squeeze juicer includes a base having a motor, a crushing chamber mounted on the base, and a screw rod arranged inside the crushing chamber. The crushing chamber includes a crushing chamber body, the crushing chamber body has a juice outlet and a residue outlet, the crushing chamber has a feeding opening and a feeding channel connected to the feeding opening, the feeding channel includes an upper opening and a lower opening connected to the feeding opening. A rotatable overturn storage container is provided at the upper opening, a rotation center of the overturn storage container traverses the upper opening, and the overturn storage container is configured for placing a material and is rotatable about the rotation center in any direction.

A filtration assembly for separating solids from liquids contained in a sample, and a method for preparing such a sample are disclosed herein. According to one embodiment, the filtration assembly includes an inner element (100) with proximal and distal ends (102,103) and a sample (200) disposed therein. A reinforcing sleeve (300) is disposed around the inner element (100) to form a sample receiver (250) with proximal and distal ends (252,253). A filter (400) is disposed at the open proximal end of the sample receiver (252) and a filtrate receiver (500) is placed over the filter (400) and threadedly engaged with the sample receiver (250) to clamp the filter (400) therebetween. Then, the receivers (250,500) are inverted and a pressure is applied to the sample (200) to force a liquid component (200a) through the filter (400) into the filtrate receiver (500), while solids (200b) are retained in the sample receiver (250).

A filtration assembly for separating solids from liquids contained in a sample, and a method for preparing such a sample are disclosed herein. According to one embodiment, the filtration assembly includes an inner element (100) with proximal and distal ends (102,103) and a sample (200) disposed therein. A reinforcing sleeve (300) is disposed around the inner element (100) to form a sample receiver (250) with proximal and distal ends (252,253). A filter (400) is disposed at the open proximal end of the sample receiver (252) and a filtrate receiver (500) is placed over the filter (400) and threadedly engaged with the sample receiver (250) to clamp the filter (400) therebetween. Then, the receivers (250,500) are inverted and a pressure is applied to the sample (200) to force a liquid component (200a) through the filter (400) into the filtrate receiver (500), while solids (200b) are retained in the sample receiver (250).

The present invention discloses a juicer, including a juicer conveying device, a juicer juice-out control device, a juicer automatic cupping device, a juicer juicing device, and an anti-pinch door sheet. The juicer conveying device conveys a material to the juicer juicing device. The juicer juicing device juices the material, and then juice enters the juicer juice-out control device. The juicer juice-out control device controls the outflow volume of the juice. The controlled juice enters the juicer automatic cupping device. The juicer automatic cupping device automatically cups the juice. After cupping, a cup can be taken away through the anti-pinch door sheet.

A juice extractor with an easily assembled and disassembled housing includes: a driving unit having a motor housing having a motor mounted at the inside thereof, a rotary shaft connected to the motor and protruded toward one side of the motor housing, and a fixing shaft disposed adjacent to the rotary shaft on the motor housing; a juice extracting unit having roller portions operated by the motor provided at the driving unit to crush, extract and transfer juice extraction materials and the housing for accommodating the roller portions thereinto; a fastening unit for detachably coupling the housing of the juice extracting unit to the motor housing; and a sensor unit having a sensor operator mounted on the housing of the juice extracting unit and a sensor mounted on the motor housing in such a manner as to be operated by a change in distance with the sensor operator.