An apparatus and method are provided for extraction compounds from raw materials. The control and manipulation of heat formed and contained within the extraction vessel or column may be vital in obtaining a certain flavor profile or intensity of the effluent extracted from the raw materials. As such, the solvent entering the apparatus to extract the raw materials may be heated to a specified temperature range with the aid of energy already formed within the extraction column. The apparatus to extract the raw materials may include a body comprising a pressure vessel capable of withstanding high temperatures and pressures. Additionally, a flow of pressurized solvent may enter the base of the extraction column, where the flow of pressurized solvent has a select temperature such that the temperature may be manipulated to obtain a distinct flavor profile of the effluent extracted from the raw materials.

A beverage making device comprising a brewing chamber configured to brew a beverage, the device comprising: a valve assembly comprising: a housing including an inlet for receiving pressurized water into the housing, a two way passage coupling the housing to the brewing chamber, an outlet configured to remove the brewed beverage from the housing, and a pressure release valve configured to close the outlet to send the pressurized water out of the two way passage to the brewing chamber when the pressurized water is supplied to the inlet, and close the inlet to receive a brewed beverage from the brewing through the two way passage when the pressurized water is not provided to the inlet.

A multi-cup drip coffee maker includes a displacing mechanism mounted inside a casing. The casing has a user interface mounted on a front panel of the casing. A first driving mechanism is mounted on an inner wall of one of two side panels of the casing, and a second driving mechanism and a control unit are mounted on an outer wall of the side panel. The first driving mechanism drives a coffee outlet seat on the displacing mechanism to move between the two side panels. The second driving mechanism drives the displacing mechanism to oscillate forward and backward. The control unit is electrically connected to the user interface and the first and second driving mechanisms, and drives the first and second driving mechanisms to individually or both operate according to a configuration signal from the user interface to fulfill time-efficient brewing of multiple cups of drip coffee with enhanced drip coffee quality.

A multi-cup drip coffee maker includes a displacing mechanism mounted inside a casing. The casing has a user interface mounted on a front panel of the casing. A first driving mechanism is mounted on an inner wall of one of two side panels of the casing, and a second driving mechanism and a control unit are mounted on an outer wall of the side panel. The first driving mechanism drives a coffee outlet seat on the displacing mechanism to move between the two side panels. The second driving mechanism drives the displacing mechanism to oscillate forward and backward. The control unit is electrically connected to the user interface and the first and second driving mechanisms, and drives the first and second driving mechanisms to individually or both operate according to a configuration signal from the user interface to fulfill time-efficient brewing of multiple cups of drip coffee with enhanced drip coffee quality.

A coffee maker includes an extractor configured to receive ground coffee and water and to extract coffee from the ground coffee, and a dispenser configured to supply water to the ground coffee in the extractor. The dispenser includes an arm that is rotatably disposed vertically above an inlet of the extractor and includes a nozzle configured to supply water to the ground coffee in the extractor, a first actuator configured to rotatably support the arm and to rotate the arm about a center of the inlet along an edge of the inlet, and a second actuator connected to the arm and configured to rotate the arm relative to the first actuator.

A coffee maker includes an extractor configured to receive ground coffee and water and to extract coffee from the ground coffee, and a dispenser configured to supply water to the ground coffee in the extractor. The dispenser includes an arm that is rotatably disposed vertically above an inlet of the extractor and includes a nozzle configured to supply water to the ground coffee in the extractor, a first actuator configured to rotatably support the arm and to rotate the arm about a center of the inlet along an edge of the inlet, and a second actuator connected to the arm and configured to rotate the arm relative to the first actuator.

A system and method are provided for extracting compounds from raw materials packed into an extraction column. The system may include a flowing solvent source connected to an extraction column to provide a flow of solvent for extracting the raw materials. The system may also include an electrodeionizer to separate positive ions and negative ions within the flowing solvent to create an imbalance of ions and transform the solvent to a deionized solvent. In further embodiments, the extraction column includes a solvent surface layer in contact with a bed of raw materials, such that the hydraulic pressure applied within the extraction column results in the formation of catalyzing energy to generate a self-perpetuating energy cycle to extract the raw materials.

A system and method are provided for extracting compounds from raw materials packed into an extraction column. The system may include a flowing solvent source connected to an extraction column to provide a flow of solvent for extracting the raw materials. The system may also include an electrodeionizer to separate positive ions and negative ions within the flowing solvent to create an imbalance of ions and transform the solvent to a deionized solvent. In further embodiments, the extraction column includes a solvent surface layer in contact with a bed of raw materials, such that the hydraulic pressure applied within the extraction column results in the formation of catalyzing energy to generate a self-perpetuating energy cycle to extract the raw materials.

An apparatus and method are provided for extraction compounds from raw materials. The control and manipulation of heat formed and contained within the extraction vessel or column may be vital in obtaining a certain flavor profile or intensity of the effluent extracted from the raw materials. As such, the solvent entering the apparatus to extract the raw materials may be heated to a specified temperature range with the aid of energy already formed within the extraction column. The apparatus to extract the raw materials may include a body comprising a pressure vessel capable of withstanding high temperatures and pressures. Additionally, a flow of pressurized solvent may enter the base of the extraction column, where the flow of pressurized solvent has a select temperature such that the temperature may be manipulated to obtain a distinct flavor profile of the effluent extracted from the raw materials.

An apparatus and method are provided for extraction compounds from raw materials. The control and manipulation of heat formed and contained within the extraction vessel or column may be vital in obtaining a certain flavor profile or intensity of the effluent extracted from the raw materials. As such, the solvent entering the apparatus to extract the raw materials may be heated to a specified temperature range with the aid of energy already formed within the extraction column. The apparatus to extract the raw materials may include a body comprising a pressure vessel capable of withstanding high temperatures and pressures. Additionally, a flow of pressurized solvent may enter the base of the extraction column, where the flow of pressurized solvent has a select temperature such that the temperature may be manipulated to obtain a distinct flavor profile of the effluent extracted from the raw materials.