A mobile terminal includes: a wireless communication unit configured to communicate with a beverage-making apparatus; a display unit; and at least one processor. The at least one processor is configured to: receive, through the wireless communication unit, beverage-making state information indicating a state of the beverage-making apparatus; and generate content to be output through the display unit, based on the received beverage-making state information of the beverage-making apparatus.

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.

A method of operating a coffee making appliance includes receiving an input from a user interface of the coffee making appliance. In response to the received input, a pump of the coffee making appliance is activated to pump an initial volume of water from a reservoir to a brew basket. The pump is then paused for a bloom time after pumping the initial volume of water. The bloom time is based on the input from the user interface. The method also includes activating the pump to pump a second volume of water from the reservoir to the brew basket after the bloom time.

A beverage maker platen overflow sensing system is disclosed. The sensing system includes a process control board (PCB) in communication with solenoid valves of a manifold, the solenoid valves controlling the flow of hot water (e.g., for brewing coffee or tea) into a server positioned in a platen of the beverage maker. The PCB further includes an overflow detection circuit connected to the solenoid valves. Two signal probes are positioned near the forward edge of the platen. Similarly, ground probes are positioned in the platen below the signal probes and providing a ground path to the PCB. The overflow detection circuit generates an electrical signal between the signal probes and detects an overflow state when fluid in the platen grounds the signal between the signal probes and the ground probes. While the overflow persists, the overflow detection circuit ceases the water flow by electrically signaling the solenoid valves to close.

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.

Beverage preparation apparatus for preparing a beverage comprising: —a water tank (2) for storing water, —a brewing unit (3) for receiving a dose of beverage ingredients, —a water line (5) for supplying water from the water tank to the brewing unit (3) including a pressure pump (4) for supplying pressurized liquid to the brewing unit and a fluid heater (29) for heating liquid, —a control unit (6) for selectively controlling the activation of the pressure pump, wherein it further comprises a fluidic interrupter (7) positionable in fluidic interruption position for interrupting the fluidic communication between the water tank (2) and the water line (5) and, reversely, positionable in fluidic communication position for restoring the fluid communication between the water tank and the water line and wherein the control unit (6) is arranged for automatically activating an anti-freeze mode by activating the fluidic interrupter (7) in fluidic interruption position and by running the pressure pump (4) to at least partially empty the water line (5) from water contained therein.

A brewer system includes a reservoir, a steep chamber movable relative to the reservoir and positioned over a mouth of the reservoir, and a filter tape positioned between the chamber and the reservoir. Brewing substance and water are added to the chamber to form a brewed beverage that passes through the filter tape and into the reservoir through the mouth.

An espresso coffee machine is described, said machine comprising: a dispensing group and a corresponding coffee boiler containing water under pressure; a heater device for heating the water in the coffee boiler; a temperature sensor for measuring the temperature of the water in the coffee boiler; a processor connected to said sensor and configured to drive said heater device so that the water in the coffee boiler is at a set reference temperature, wherein said processor comprises a feedback system; and wherein the value of said set reference temperature is varied as a function of at least one of the following parameters: (a) a first parameter which is a function of the time elapsed from an operating cycle of the machine or a frequency of use of the machine within a time interval; (b) a second parameter which is a function of the temperature of a component of the machine; and (c) a third parameter which is a function of the environment.

A method of recognizing a type of coffee from reference types of coffee, wherein each of the reference types of coffee is associated with a respective reference signal and wherein each type of coffee is associated to a characteristic combination of volatile organic compounds released from the type of coffee, may include: sensing, by one or more sensors, presence and concentration of one or more volatile organic compounds in a mixture of volatile organic compounds released from the type of coffee; generating a signal representative of the type of coffee according to the sensed one or more volatile organic compounds and the respective concentrations of the sensed one or more volatile organic compounds; comparing the generated signal with the reference signal associated with each of the reference types of coffee; and generating a recognition signal in response to the comparing of the generated signal with the reference signals.

Methods, apparatus, and system to distribute or compact coffee grounds, such as to form a puck in a portafilter. The methods, apparatus, and system may be used to compact coffee grounds wherein a resulting puck of coffee grounds in the portafilter has an even level, a uniform and or continuous density distribution, results in no or reduced formation of channels, no or reduced squirting of extracted coffee, and results in consistent and repeatable results. The methods, apparatus, and system may be used to form multiple layers in a puck, for use in preparing layered espresso.