A method of forming frozen beverage blocks from a liquid beverage. The method may include introducing a beverage into a hot beverage reservoir of a beverage receiving subsystem to initiate the process. Next, the beverage may flow from the hot beverage reservoir of the beverage receiving subsystem into a cooling subsystem. The flow from the hot beverage reservoir into and through the cooling subsystem may be done entirely via gravity. Cool air may be blown across the cooling subsystem to cool the beverage as the beverage flows through the cooling subsystem. Upon the temperature of the beverage being measured at or below a predetermined lower threshold temperature, the beverage may be permitted to flow, via gravity, from the cooling subsystem into a cool beverage reservoir of a freezing subsystem. The freezing subsystem may be configured to convert the beverage from a liquid into frozen beverage blocks.

The present invention refers to a vending machine for juices made of natural fruit comprising a structure or framework, a module for storing and dispensing fruits having compartments for preserving fruit, helical bars for transportation disposed in each compartment which transport the pieces of fruit without damaging them, weighing hoppers that receive, measure and dose the weight of the pieces of fruit by means of load cells, a means for transferring the dosed fruit, a blending module with the upper part of the blender vessel modified to eliminate the need for closure or covering, modules for transporting liquids with peristaltic pumps and with tubular conduits to control accurately the amount of liquid supplied, a module for supplying food additives, a container dispenser, a module for the interaction between the user and the machine equipped with a touch-screen, a cooling module, a control module and preferably a modified module for drainage and safety.

A beverage mixing system/method allowing faster mixing/blending of frozen beverages is disclosed. The system/method in various embodiments utilizes inductive coupling to introduce heat into the frozen beverage during the mixing/blending process via a rotating driveshaft and attached mechanical agitator to speed the mixing/blending process. Exemplary embodiments may be configured to magnetically induce heat into the driveshaft and/or mechanical agitator mixing blade to affect this mixing/blending performance improvement. This heating effect may be augmented via the use of high power LED arrays aimed into the frozen slurry to provide additional heat input. The system/method may be applied with particular advantage to the mixing of ice cream type beverages and other viscous beverage products.

The present invention relates to a high protein shelf stable powder composition comprising form about 52 to 80% of a protein source having a lipid content, from about 5-18% of a protein encapsulated fat, from about 5-18% of a mineral source that is whey permeate, lactose, sweet whey powder or a dairy mineral blend or a mixture thereof and from about 0.2% to 5.0% stabilizing agent or a mixture of stabilizing agents. The composition may also contain flavorings, salts, starch, sweetener and/or soluble fiber. The amounts are by weight of the composition. The invention also relates to preparing a high protein frozen confection from the shelf stable powder composition.

The present invention relates to a high protein shelf stable powder composition comprising form about 52 to 80% of a protein source having a lipid content, from about 5-18% of a protein encapsulated fat, from about 5-18% of a mineral source that is whey permeate, lactose, sweet whey powder or a dairy mineral blend or a mixture thereof and from about 0.2% to 5.0% stabilizing agent or a mixture of stabilizing agents. The composition may also contain flavorings, salts, starch, sweetener and/or soluble fiber. The amounts are by weight of the composition. The invention also relates to preparing a high protein frozen confection from the shelf stable powder composition.

A method for dispensing a beverage container to a consumer. The method includes receiving in a beverage container dispenser a first beverage container that contains a beverage corresponding to a beverage selection of a user. The method further includes dispensing a second beverage container containing the beverage from a temperature-regulated compartment of the beverage container dispenser. The second beverage container that is dispensed from the temperature-regulated compartment corresponds to the beverage selection of the user.

The invention relates to a device (10), a container (20), a system (100) comprising the device (10) and the container (20), and a method for delivering frozen or chilled beverages. The device (10) is provided for receiving a container (20) comprising a frozen product and for processing the frozen product of the container (20) for delivering a frozen or chilled beverage, wherein the container (20) comprises a first end (20a), a second end (20b) and a sidewall (20c) extending between the first end (20a) and the second end (20b). The device (10) comprises a slicing element (60) and a driving unit (50) configured to rotate the container (20) and thus the frozen product about a rotation axis for rotating the frozen product relative to the slicing element (60) in order to slice the frozen product. The device (10) further comprises a reading unit (41) configured to read a machine-readable identification element (22) of the container (20), wherein the reading unit (41) is positioned such that an identification element (22) provided on the sidewall (20c) of the container (20) is readable by the reading unit (41), when the container (20) is rotating about the rotation axis.

A tubeless smoothie vending machine including a tubeless electro-mechanically actuated dispensing nozzle attached to each smoothie dispensing tank, a cup retrieval system to retrieve an empty cup and move the cup to each selected dispensing nozzle, a portal in the cup retrieval system to transfer the cup through the cup retrieval system, a receiving shelf to receive the filled cup, a dispenser system to drop dry food product into the beverage filled cup, and an access door to open when the beverage filled cup is ready to vend to the customer. Tubes for delivering beverage to the cup are eliminated. A consolidated smoothie vending machine having a plurality of integrated smoothie blenders, a dry food supplement delivery assembly, a straw delivery assembly, and a lid delivery assembly. In one example, the smoothie blenders are stacked. In one example, the smoothie blenders are attached to sliding shelving.

A machine for making and dispensing liquid or semi-liquid food products, includes, in combination: a container for containing liquid or semi-liquid products; a thermal treatment cylinder contained inside the container and having an axis that is inclined relative to the vertical; a stirrer mounted to the outside of the thermal treatment cylinder; a thermal system including a heat exchanger associated with the thermal treatment cylinder, wherein the container for containing liquid or semi-liquid products is defined by a first, inside wall and a second, outside wall, the first, inside wall and the second, outside wall forming between them a gap that is not affected by the liquid or semi-liquid products.

A refrigeration subsystem removably received within a base machine to cool an object. The subsystem includes a body with an opening that receives the object. An evaporator thermally communicates with the object, which is cooled by refrigerant flowing through the evaporator. A compressor receives the refrigerant downstream of the evaporator and increases a refrigerant pressure. A condenser receives the refrigerant downstream of the compressor, which cools the refrigerant. An expansion device receives the refrigerant downstream of the condenser and decreases its pressure, the evaporator being downstream from the expansion device. A refrigerant circuit fluidly couples the evaporator, compressor, condenser, and expansion device such that the refrigerant flows therebetween, all of which are coupled to the body and move together therewith. The refrigerant circuit forms a closed loop that remains unbroken when the body of the refrigerant subsystem is removed from the base machine.