A device for automatically brewing beer that automates the tasks and operations of the brewing process. The device has an insulated enclosure, a brewing chamber positioned within the enclosure, a flexible brew pouch positioned below and fluidly interconnected to the brewing chamber, wherein the flexible brew pouch can be adjusted between a first volume and at least a second volume that is greater than the first volume, a yeast collection bin positioned below and interconnected to the brew pouch, and at least one source of heat positioned within the enclosure. A temperature sensor is associated with the brewing chamber. A pressure sensor, a near infrared sensor, and a heat exchanger are associated with the brew pouch. A controller operates the heat exchange assembly and the source of heat according to data received from the temperature sensor, the near infrared sensor, and the pressure sensor and a recipe that is uploaded to the controller by a user to automatically brew beer.

The invention regards an aroma extraction unit, comprising: a hydration tank containing a mixture of plants or parts thereof and a liquid, said tank configured to contain a positive gas flow pressure, a shearing unit configured for shearing the plants or parts thereof, a hydrodynamic cavitation unit, and at least one circulation unit, wherein the hydration tank, shearing unit, cavitation unit are in fluid communication, and the at least one circulation unit is configured for circulating the mixture from the tank into the shearing unit, further into the cavitation unit, and from the cavitation unit back into the tank and/or shearing unit.

A system and method for generating wort utilizing steam injection heating and stratified flow. The system mixes a fine ground grain with water to form a slurry. The slurry is pumped through a steam injection heater to form a mash. The heated mash enters into a stratified vessel that creates a stratified temperature profile from a first end to a second end. The stratified heating vessel allows the mash to flow from the first end to the second end without internal mixing. After retention within the mash coil, the wort is directed to a mash filtration unit. After filtration, the wort enters into a boil kettle and is heated using a second steam injection heater. The boil kettle includes a spray head that directs brewing liquor onto the wort to reduce foam within the boil kettle. Finally, the wort passes through a scraped surface sieve that removes particles from the heated wort.

The invention relates to a method for recovering beer from cold-hopped beer (20). According to the invention, the cold-hopped beer (20) is supplied to a decanting centrifuge (50) and is clarified by the decanting centrifuge (50) such that a separated solid substance (70) preferably preponderantly has hop sediments, and a liquid phase (80) is clarified beer.

The invention relates to a method for recovering beer from cold-hopped beer (20). According to the invention, the cold-hopped beer (20) is supplied to a decanting centrifuge (50) and is clarified by the decanting centrifuge (50) such that a separated solid substance (70) preferably preponderantly has hop sediments, and a liquid phase (80) is clarified beer.

A process that provides for the reuse of yeast biomass used in the alcoholic fermentation of both sugarcane and corn in independent or integrated processes with steps of separation and reuse of solids prior to distillation and which are used in the process itself and in other industrial applications such as the production of high protein content (DDG/DDGS) ration, due to the alcohol recovery of the process, biodiesel, cell wall and yeast extract, as well as energy generation. The process also includes a drying step using indirect contact dryers operating with low pressure, non-noble vapors, such as plant vapor and exhaust vapor, and with the recovery of the ethanol contained in the wet cake.

Embodiments described herein generally relate to systems and methods for processing non-fermented liquids. In some embodiments, non-fermented liquids may be processed into fermentable liquids in relatively short time (e.g., less than or equal to 30 minutes). In certain embodiments, the non-fermented liquids may be processed in relatively small batches (e.g., having a volume of less than or equal to 2 liters). The systems and methods described herein may be useful for producing fermented (e.g., alcoholic) beverages by a consumer. Advantageously, the systems and methods may be for use by a consumer where, upon introduction of a non-fermented liquid into the system, a fermented beverage is produced (e.g., in relatively small batches and/or in relative short times) as compared to traditional fermentation systems and methods (e.g., requiring relatively long fermentation times and/or relatively large batches). In certain embodiments, the systems and methods produce fermented beverages in a substantially continuous manner (e.g., as compared to traditional fermentation systems which utilize batch and/or semi-batch processes). Such systems may be useful for, for example, on-demand brewing of alcoholic beverages.

Compositions and methods are disclosed for stabilizing the flavor of a fermented beverage, most particularly beer, by the addition of a composition comprising a tannin and a solid carrier prior to, or during early stages of, fermentation of the beverage. The invention is also directed to the fermented beverage prepared by such a method. The composition may include at least one polyphenol therein and may be in the form of a pellet.

A device for extracting aroma substances from vegetable aroma carriers into a brewing liquid includes a solids separating device for separating the vegetable aroma carriers from the brewing liquid in flow, the solids of the aroma carriers being held back in the solids separating device. The device comprises a heater for heating the suspension of brewing liquid and aroma carriers to an isomerization temperature at which the -acids contained in the aroma carriers are converted into iso--acids.

It has unexpectedly been found that Pichia spp. strains have advantageous properties useful in the beer fermentation process. In particular, Pichia spp. yeast strains can be combined with normal beer yeast strains and different hop varieties in a fermentation process to produce synergistic effectsnamely, the increased production of esters in the fermentation product. More specifically, the yeast can be used to produce increased levels of isoamyl acetate, isobutyl acetate, ethyl propionate, ethyl valerate, ethyl butyrate, ethyl decanoate and ethyl octanoate in beer. In addition, the Pichia spp. strain interacts differently with different hop varieties, so the flavor profile of beer can be tuned by using different combinations of Pichia spp. strains and hops. The present invention relates to a method of brewing beer using a Pichia spp. yeast strain and at least one hop variety, a beer obtainable by such a method and use of a Pichia spp. yeast strain according to the present invention.