A blender using different power modes is disclosed. Exemplary implementations may include a base assembly, a container assembly, an electrical motor, a blending component, a control interface, control circuitry, and/or other components. The control circuitry may be configured to make different types of detections related to the availability and/or usage of electrical power, and may control the electrical motor using at least two different power modes of operation, thus providing different amounts of power to the electrical motor in different power modes of operation.

A blender using different power modes is disclosed. Exemplary implementations may include a base assembly, a container assembly, an electrical motor, a blending component, a control interface, control circuitry, and/or other components. The control circuitry may be configured to make different types of detections related to the availability and/or usage of electrical power, and may control the electrical motor using at least two different power modes of operation, thus providing different amounts of power to the electrical motor in different power modes of operation.

A liquid brewing device includes a base housing a motor and at least one base magnet rotatable by the motor relative to the base, a pitcher having an interior volume, and a brew basket for receiving brewing ingredients, the brew basket being removably insertable positioned in the interior volume of the pitcher. An agitator is positioned entirely within and rotatable relative to the brew basket, the agitator being operatively coupled to at least one agitator magnet. The at least one agitator magnet is magnetically coupled to the at least one base magnet, such that rotation of the at least one base magnet by the motor operates to rotate the at least one agitator magnet and the agitator.

A cooking assembly can include a cooking vessel, a mixer, and a motor. The cooking vessel can include a bottom contact portion including a first bore therethrough, a heating portion spaced above the bottom contact portion and including a second bore therethrough, and a sidewall connected to the heating portion and together with the heating portion configured to retain food in the cooking vessel. The mixer can be located within the cooking vessel, where the mixer configured to rotate relative to the heating portion. The motor can be connected to the mixer via the first bore and the second bore to drive the mixer to rotate.

A cooking assembly can include a cooking vessel, a mixer, and a motor. The cooking vessel can include a bottom contact portion including a first bore therethrough, a heating portion spaced above the bottom contact portion and including a second bore therethrough, and a sidewall connected to the heating portion and together with the heating portion configured to retain food in the cooking vessel. The mixer can be located within the cooking vessel, where the mixer configured to rotate relative to the heating portion. The motor can be connected to the mixer via the first bore and the second bore to drive the mixer to rotate.

A food processor comprises: a housing which includes a container-accommodating chamber; an accommodating tank which is accommodated in the container-accommodating chamber, has an opening portion for inputting food ingredients, and has an accommodating space for accommodating the food ingredients input through the opening portion; a cover which closes the opening portion while coupled to the accommodating tank, and has an air exhaust part communicating with the accommodating space; a vacuum pump which is provided in the housing; and a vacuum port which is configured to be switched between a first state in which the vacuum port is in close contact with the air exhaust part inside the container-accommodating chamber, and a second state in which the vacuum port is spaced apart from the air exhaust part, the vacuum port including an exhaust line for communicatively connecting the vacuum pump and the air exhaust part in the first state.

A food processor comprises: a housing which includes a container-accommodating chamber; an accommodating tank which is accommodated in the container-accommodating chamber, has an opening portion for inputting food ingredients, and has an accommodating space for accommodating the food ingredients input through the opening portion; a cover which closes the opening portion while coupled to the accommodating tank, and has an air exhaust part communicating with the accommodating space; a vacuum pump which is provided in the housing; and a vacuum port which is configured to be switched between a first state in which the vacuum port is in close contact with the air exhaust part inside the container-accommodating chamber, and a second state in which the vacuum port is spaced apart from the air exhaust part, the vacuum port including an exhaust line for communicatively connecting the vacuum pump and the air exhaust part in the first state.

The present disclosure relates to a grinding machine and an assembling method thereof. The grinding machine includes a container, a grinding assembly, and a sealing base. A bottom portion of the container defines a juice outlet. The sealing base seals the juice outlet. The sealing base is detachably connected with the container. The grinding assembly includes a cutting tool, an upper grinding disc, and a lower grinding disc arranged in sequence from top to bottom. A drive shaft is rotatably arranged on the sealing base. The cutting tool and the lower grinding disc are fixed on the drive shaft. The upper grinding disc is fixed on the sealing base. A first positioning step configured to position the upper grinding disc is formed on an inner wall of the juice outlet. A first elastic sealing piece is arranged between the upper grinding disc and the first positioning step.

The present disclosure relates to a grinding machine and an assembling method thereof. The grinding machine includes a container, a grinding assembly, and a sealing base. A bottom portion of the container defines a juice outlet. The sealing base seals the juice outlet. The sealing base is detachably connected with the container. The grinding assembly includes a cutting tool, an upper grinding disc, and a lower grinding disc arranged in sequence from top to bottom. A drive shaft is rotatably arranged on the sealing base. The cutting tool and the lower grinding disc are fixed on the drive shaft. The upper grinding disc is fixed on the sealing base. A first positioning step configured to position the upper grinding disc is formed on an inner wall of the juice outlet. A first elastic sealing piece is arranged between the upper grinding disc and the first positioning step.

A cup structure includes a bottom, a body and a top cover. A bottom edge of the body is detachably sleeved at the bottom. The top cover is covered on a top of the body. The bottom includes a base, a driving assembly, a transmitting assembly and a cover. A top surface of the base is sunk inward and forms an accommodating space. The driving assembly is disposed in the accommodating space. The transmitting assembly is geared into the driving assembly. The cover is disposed on the transmitting assembly, wherein the cover includes a protrusion, a water-blocking layer and a mixer. The mixer is disposed on a top of the protrusion and includes at least one mixing blade. A power is transmitted to the mixer by the transmitting assembly after the power is generated by the driving assembly, so that the at least one mixing blade is rotated.