A kitchen appliance includes a first reservoir for receiving a liquid to be used for preparing a beverage and a hot water generator (‘HWG’) which has an inlet end, an outlet end and a passageway therebetween. The inlet end of the HWG is connected to the first reservoir. Liquid from the first reservoir flows into the HWG through the inlet end. A second reservoir is connected to the outlet end of the HWG. The second reservoir includes a discharge port. A fluid path connects the first and second reservoirs and bypasses the HWG. The kitchen appliance is operable for both pressurized brew/heat cycles and un-pressurized brew/heat cycles.

A kitchen appliance includes a first reservoir for receiving a liquid to be used for preparing a beverage and a hot water generator (‘HWG’) which has an inlet end, an outlet end and a passageway therebetween. The inlet end of the HWG is connected to the first reservoir. Liquid from the first reservoir flows into the HWG through the inlet end. A second reservoir is connected to the outlet end of the HWG. The second reservoir includes a discharge port. A fluid path connects the first and second reservoirs and bypasses the HWG. The kitchen appliance is operable for both pressurized brew/heat cycles and un-pressurized brew/heat cycles.

The brewing system disclosed herein includes a moving inlet nozzle for use in intermixing hot water and coffee in a coffee cartridge. The inlet nozzle may include one or more flow ports that inject hot water into an inner chamber of the coffee cartridge at select angles, locations and pressures to create the desired fluidized mixture of hot water and beverage medium.

The brewing system disclosed herein includes a moving inlet nozzle for use in intermixing hot water and coffee in a coffee cartridge. The inlet nozzle may include one or more flow ports that inject hot water into an inner chamber of the coffee cartridge at select angles, locations and pressures to create the desired fluidized mixture of hot water and beverage medium.

A coffee and tea brewing system includes a carafe assembly including a container configured to hold the brewed coffee or tea; a brewing assembly configured to be selectively coupled to the container of the carafe assembly for brewing of coffee or tea and selectively removed from the container of the carafe assembly when serving the brewed coffee or tea, the brewing assembly comprising a mesh filter assembly configured to allow for separation of the coffee grounds or tea leaves from the brewed coffee or tea, and an agitation mechanism configured to selectively agitate the coffee grounds or tea leaves and associated brewing coffee or tea during brewing; and a heating assembly configured to support the carafe assembly and selectively add heat thereto. The agitation is through manual manipulation of a paddle adjacent the mesh filter assembly. A method of brewing coffee or tea is disclosed using the system.

A coffee and tea brewing system includes a carafe assembly including a container configured to hold the brewed coffee or tea; a brewing assembly configured to be selectively coupled to the container of the carafe assembly for brewing of coffee or tea and selectively removed from the container of the carafe assembly when serving the brewed coffee or tea, the brewing assembly comprising a mesh filter assembly configured to allow for separation of the coffee grounds or tea leaves from the brewed coffee or tea, and an agitation mechanism configured to selectively agitate the coffee grounds or tea leaves and associated brewing coffee or tea during brewing; and a heating assembly configured to support the carafe assembly and selectively add heat thereto. The agitation is through manual manipulation of a paddle adjacent the mesh filter assembly. A method of brewing coffee or tea is disclosed using the system.

A beverage preparation system for preparing beverages within a container by just adding water is provided. The beverage preparation system embodies an enclosure device forming a beverage admixture-filled enclosure with a permeable first membrane extending between first and second boundary elements. Attachment points may be disposed along the first and second membrane elements so as to enable formation of the beverage admixture-filled enclosure along the interior walls of the container by adhering the attachment points thereto. Alternatively, the enclosure device may provide a second membrane extending between the first and second boundary elements, forming a beverage admixture-filled reservoir so that the enclosure device may be received into and attached to any suitably sized pre-existing container. Whereby adding a suitable liquid to the container, the liquid permeates the first membrane so as to interact with the beverage admixture, resulting in a beverage mixture the user may drink from the container.

Disclosed is a tea beverage and production method therefor. The tea beverage comprises tea, reverse-osmosis water which is deoxidized and deionized, and a food antioxidant, and the oxygen content in the freshly packaged tea beverage is ≦1 mg/L.

Disclosed is a tea beverage and production method therefor. The tea beverage comprises tea, reverse-osmosis water which is deoxidized and deionized, and a food antioxidant, and the oxygen content in the freshly packaged tea beverage is ≦1 mg/L.

Disclosed is a microcapsule containing: (i) a microcapsule core having an active material, and (ii) a microcapsule wall formed of a first polymer and second polymer. The first polymer is a sol-gel polymer. The second polymer is gum arabic, purity gum ultra, gelatin, chitosan, xanthan gum, plant gum, carboxymethyl cellulose, sodium carboxymethyl guar gum, or a combination thereof. The weight ratio between the first and second polymer is 1:10 to 10:1. Also disclosed are processes for preparing the microcapsule and uses of the microcapsules in consumer products.