The present disclosure is for an electronic control system for a brewing device for a machine for preparing beverages, in particular coffee or tea. The brewing device comprises a brewing chamber having an opening through which a material to be brewed may be loaded and discharged; a closing body movable away from and towards a sealed closing position of the opening angularly spaced apart from the closing position, through an intermediate ejection position, in which the closing body is raised with respect to the closing position along the longitudinal axis of the brewing chamber; a piston slidably mounted in the brewing chamber in a position axially opposite the closing body; a first electric actuating device for the movement of the closing body; and a second electric actuating device for the movement of the piston. The electronic control system is configured to be arrangeable in the brewing device and comprises a sensory system configured to output electrical signals to allow the reaching, by the closing body, of the opening, closing and ejection positions to be sensed, and the axial position of the piston in the brewing chamber to be determined, and an on-board electronic control unit configured to be connectable to the sensory system to receive electrical signals therefrom, to the first and second electric actuating device to supply electrical control signals thereto, and to an electronic control unit of the beverage preparation machine external to the brewing device to receive therefrom commands relating to the operation of the brewing device. The on-board electronic control unit is further configured to execute commands received from the external control unit to responsively output, also based on the electrical signals received from the sensory system, electrical control signals for the electric actuating devices.

A portafilter for use with an espresso coffee machine includes a handle, a receptacle, and a top cover. The receptacle has a void or reservoir that contains a single-use coffee cartridge (e.g., a K-CUP® cartridge). A bottom surface of the receptacle has needles directed into the void or reservoir which pierce a bottom surface of the cartridge, thereby creating holes in the bottom of the cartridge to allow liquid (e.g., hot coffee) to flow out of the cartridge. A hole in the bottom surface of the receptacle allows liquid hot coffee to flow out of the receptacle and into a coffee cup. The top cover includes tubular protrusions directed downward which pierce a top surface of the cartridge, thereby creating holes in the top surface of the cartridge to allow hot water from the espresso machine to flow through the tubes and into the top of the cartridge.

A machine (1) for preparing and dispensing a beverage (2) has: a capsule extraction unit (10) having a first part (11) and a second part (12) that are relatively movable between a distant position for inserting a capsule (3) and a close position for extracting such capsule (3); a control unit (40) for controlling the extraction unit (10) to extract such capsule (3); an outlet (20) for dispensing said beverage (2) formed by extracting such capsule (3) to a user-receptacle (4) located in a receptacle placing area; and a detection arrangement (30) connected to the control unit (40) for detecting the presence of such receptacle (4) in the placing area. The unit (10) has an actuator (13) configured to relatively move the first and second parts (11, 12) between their distant and close positions. The actuator (13) is controlled by the control unit (40) to relatively move the first and the second parts (11, 12) when the detecting arrangement (30) detects the presence of said receptacle (4) in the receptacle placing area.

An apparatus for making a beverage using a capsule (3), (4), wherein, respectively for a first and a second type of beverage selectable, first data and second data are saved which comprise a first and a second supplying start temperature value, a first and a second steady-state supplying temperature value, a first and a second total supplying time and a first and a second activation mode for the pump (16), and wherein an electronic control unit (19) is programmed to cause the supplying respectively of the first and second type of beverage using the first data and the second data for controlling a pump (16) and a boiler (17); wherein the first total supplying time comprises a pre-infusion time, a wait time and an infusion time; and wherein the first activation mode comprises an electricity supply to the pump (16) with an average power that is greater than that in the second activation mode. A capsule is also claimed, which is usable with the apparatus and the system which comprises the apparatus and two different capsules for making two different beverages.

The document describes an assembly of a capsule (5) and brew chamber (3) for a beverage preparation machine. The brew chamber (3) has a first brew chamber part (7) including a cavity (10) for the capsule (5), and knives (11) for piercing the capsule (5). The aluminum capsule body (15) is frusto conical shaped and has a bottom (20), a side wall (21), a flange (22) and a lid (17) for closing the capsule (5). The flange (22) is configured to be held between the first and a second brew chamber parts (7, 8), to provide a seal (30) cooperating with a rim of the brew chamber parts (7, 8). The bottom (20) includes a slanted wall portion (35) under an angle with a longitudinal axis through the capsule (5), and configured for cooperating with the knives (11) which engage therewith upon closing of the brew chamber (3). This enables centering of the capsule (5) relative to the central axis of the brew chamber (3) prior to piercing of the capsule.

A beverage brewer includes a brewing chamber, a hollow injection nozzle, a rotation member, and a motor. The brewing chamber is configured to receive and hold a brewing cartridge. The injection nozzle is arranged in fluid communication with a liquid supply and configured to enter a brewing cartridge when the brewing cartridge is disposed in the brewing chamber and to provide fluid communication from the liquid supply to an interior of the brewing cartridge. The rotation member is arranged at a periphery of the brewing chamber. The motor is configured to rotate the rotation member. The beverage brewer can also include a hollow extraction nozzle arranged opposite an opening of the brewing chamber and configured to enter the brewing cartridge when the brewing cartridge is disposed in the brewing chamber and to provide fluid communication from an interior of the brewing cartridge to an exterior of the brewing chamber.

A beverage brewer includes a brewing chamber, a hollow injection nozzle, a rotation member, and a motor. The brewing chamber is configured to receive and hold a brewing cartridge. The injection nozzle is arranged in fluid communication with a liquid supply and configured to enter a brewing cartridge when the brewing cartridge is disposed in the brewing chamber and to provide fluid communication from the liquid supply to an interior of the brewing cartridge. The rotation member is arranged at a periphery of the brewing chamber. The motor is configured to rotate the rotation member. The beverage brewer can also include a hollow extraction nozzle arranged opposite an opening of the brewing chamber and configured to enter the brewing cartridge when the brewing cartridge is disposed in the brewing chamber and to provide fluid communication from an interior of the brewing cartridge to an exterior of the brewing chamber.

A system for making beverages comprising a brewing unit (2) and a capsule (4) containing a powdered food substance (5), the capsule (4) comprising a recognition element (11) placed inside an outer casing (6), wherein the brewing unit (2) comprises a first piercing unit (17), a lighting device (26) configured to light the recognition element (11), a detecting device (13) configured to detect a return light radiation from the recognition element (11) and an electronic control unit programmed to execute a comparing step, wherein real data are compared with saved reference data and to manage brewing in a different way if the real data match reference data or do not, compared with if the comparing step indicates that the real data do not match the reference data, wherein the reference data comprise one or more combinations of division of the total intensity received in a main band, into a plurality of separate secondary bands of wavelengths, which are included in the main band.

Coffee machine having a water system in which pressurized hot water circulates, at least one dispensing unit fed with pressurized hot water, a first filter holder housing a first filter for the preparation of espresso coffee, a second filter for the preparation of American coffee, having a funnel-shaped basket which with an upper collar with a cylindrical shape, which is inferiorly joined with a conical hopper perforated with a plurality of holes.

Systems and process for preparing beverages, in particular espresso coffee and similar aromatic beverages, based upon a beverage preparation apparatus that has a beverage preparation device adapted to be actuated between open and closed positions by an actuation disposition that includes an electric motor whose operation can be regulated by a control mechanism, whereby the actuation disposition includes an actuation monitoring mechanism adapted to provide monitoring of the circular movement of a driving cam so that the control mechanism can therewith better regulate the electric power supplied to said electric motor.