The invention relates to an apparatus for heating and foaming a liquid, in particular a beverage, comprising a steam line (6), which can be connected to a steam generator (1); a pressurized gas line (4), which can be connected to a pressurized gas source (2); and a conveying means (3), connected to the steam line (6) and the pressurized gas line (4), for generating and transferring a steam/gas mixture into the liquid, and a controllable switching valve (5), wherein hot steam is supplied to the conveying means (3) via the steam line (6) and a pressurized gas flow under a defined constant pressure is supplied via the pressurized gas line (4) and pressure pulses (p) are generated from the pressurized gas flow by means of the switching valve (5). In order to damp the generated pressure pulses, the conveying means (3) comprises an expansion chamber (15) having a nozzle (14) arranged on the downstream end of the expansion chamber (15).

The present disclosure discloses a yogurt maker and its method of use for using the same. A vertical upwardly extending mixing container protrusion is set at the bottom of the mixing container of the yogurt maker and a mixing head is detachably sleeved on the mixing container protrusion, and the rotation of the mixing head is driven by a power device so that the mixing head can mix the mixture in the mixing container well. At the same time, a temperature sensor is installed at the bottom of the mixing container to monitor the temperature of the mixing container, so as to ensure constant heat preservation conditions in different environments. The mixing device can be detached easily, which eliminates hygienic blind spots and ensures that the yogurt maker can be cleaned easily after making yogurt.

A device for the processing of liquids and/or solids includes a disposable layer adapted to shield a working surface from coming into contact with, and being fouled by, the processed liquids and/or solids, and apparatus suitable to apply a negative pressure in a gap between the disposable layer and the working surface, thereby causing the disposable layer to adhere to the working surface.

A milk powder brewing machine comprising a shell, a mixing bin, a milk powder box, a water storage tank, a constant-temperature bin, a drip tray, a thick-film heater, a spiral cooling pipe and a controller. An air extraction port is provided on the mixing bin, and a moisture-proof assembly is arranged above the air extraction port. The moisture-proof assembly comprises a draught fan and a wind-shield cover. Water outlet of the water storage tank is connected to a cooling pipe, and a spiral pipe is arranged in the cooling pipe. A normal-temperature water outlet is connected with the cooling pipe, which is further connected with the thick-film heater. The thick-film heater is connected with a spiral cooling pipe, which is further connected with the constant-temperature bin through a spiral pipe. The present disclosure is moisture-proof, may be conveniently disassembled, and is capable of improving the cooling effect.

An automated frothing assembly. The automated frothing assembly has a wand module that includes an elongate member having an inlet, one or more outlets, and a fluid passageway extending between and in fluid communication with the inlet and the plurality of outlets. At least one of the one or more outlets extends parallel to a vertical plane that includes the centerline of the elongate member and at an acute angle relative to a horizontal plane that is perpendicular to both the vertical plane and the centerline of the elongate member. The assembly further includes an actuator configured to be operatively coupled to the wand module and to drive the movement of at least a portion of the wand module along an axis, and an electronic controller configured to be electrically coupled to the actuator and to control the operation of the actuator to control the movement of the wand module.

Pumping and foaming device (100) comprising a pumping and foaming unit (102) rotatable around a shaft (130) by driving means (104), the pumping and foaming unit (102) comprising a pumping element (110) whose rotation pumps both air and fluid and mixes them; the pumping and foaming unit (102) further comprising a foaming element (120) whose relative rotation in a foaming chamber (121) drives the mixture of air and fluid coming from the pumping element (110) under a certain level of shear stress which allows this mixture to be foamed.

A bottle warming apparatus is disclosed that combines heating and agitating of a bottle and its contents in order to achieve even warming, as well as, mixing the contents of the bottle.

The invention refers to a mixing and foaming device (300) for mixing a powder food or beverage product with a fluid and further foaming said mixture, the device (300) comprising a mixing, pumping and foaming unit (102), an air entry (30) and a fluid inlet (21); the mixing, pumping and foaming unit (102) comprising a pumping element (110) whose rotation allows both powder and fluid to enter a foaming chamber (121) of the mixing, pumping and foaming unit (102), where a foaming element (120) rotates relatively within the foaming chamber (121), subjecting the mixture of fluid, powder and optionally air to a certain level of shear stress which allows this mixture to mix and/or to foam. The invention further refers to a method for providing foam from a food or beverage product powder using such a device (300).

A novel device for frothing milk and corresponding method are disclosed. The frothing device preferably comprises a rotatable shaft, an impeller rotatable by the shaft, and a screen disposed about the bottom of the impeller downstream of milk being pushed by the impeller. In another embodiment, the frothing device may further comprise a pitcher having a bottom wall, wherein the rotatable shaft extends upward from the bottom wall of the pitcher. This embodiment may further comprise a heater in the base of the pitcher. In yet another embodiment, the frothing device may further comprise a pitcher having a bottom wall, wherein the rotatable shaft extends upward from the bottom wall of the pitcher. This embodiment may further comprise a housing having a heater and a nub extending upwardly from the housing. The nub is configured to engage an opening at the bottom of the shaft for rotating the shaft. The disclosed embodiments advantageously create foam and further break the foam bubbles down into microscopic bubbles resulting in a silky smooth foam-textured milk without the conventional use of a steam wand or other such device.

A machine (1) for homogenising a food substance has: a container (10) with a side wall (11) and a bottom wall (12) delimiting a cavity (10); an impeller (30) with an impelling member (31) forming an impelling surface (31,31,31) that is drivable in rotation (r) about a central axial direction (30) of the impelling surface (31,31,31) for imparting a mechanical effect to the food substance; and a module (20) which has a housing means (22) that contains an inner chamber (22,22a) and that delimits a seat (21) for the container (10), the chamber (22,22a) containing an electric motor (24). The electric motor (24) has an output drive axis (24) with a driver device (24) configured to drive a follower device (35) of the impeller (30). The driver device (24) and the follower device (35) are magnetically coupled through a sidewall (11) and/or bottom wall (12) of the container (10). The driver device (24) comprises a ferromagnetic or magnetic field-generating element (24a) that is arranged to be magnetically coupled to a corresponding ferromagnetic or magnetic field-generating element (36) of the follower device (35). The follower device (35) extends over a predominant part of the bottom wall (12) of the container (10) or across a substantial part of the wall (12) along a diameter thereof. The driver device (24) extends over a predominant part of a bottom part of the seat (21) or across a substantial part of the bottom part of the seat (21) along a diameter thereof. The ferromagnetic and magnetic field generating elements (24a,36) are positioned at extremal or peripheral parts of the follower device (35) and of the driver device (24).