An additive dispensing device for dispensing of additives into a pressurised vessel, more particularly a fermentation vessel of a brewing system, is disclosed. The device has a vessel body including a chamber, the chamber having a closed end and an open end. A pressure release means is provided between the chamber and atmosphere. A controllable valve positioned between the closed end and the open end, configured to selectively open and close a flow path between the closed end and the open end.

An additive dispensing device for dispensing of additives into a pressurised vessel, more particularly a fermentation vessel of a brewing system, is disclosed. The device has a vessel body including a chamber, the chamber having a closed end and an open end. A pressure release means is provided between the chamber and atmosphere. A controllable valve positioned between the closed end and the open end, configured to selectively open and close a flow path between the closed end and the open end.

A brewing plant, comprising: a hot water storage device, including a high temperature portion and a low temperature portion, at least one high temperature water inlet, at least one high temperature water outlet, at least one low temperature water inlet, at least one low temperature water outlet; a mash container; a lauter tun or a mash filter flow connected with the mash container by a mash conduit; a wort kettle including a lauter wort inlet, a wort outlet, and an exhaust vapor condenser including a low temperature water connection and a high temperature water connection, wherein the lauter wort inlet is directly or indirectly connected through a lauter wort conduit with the lauter tun or the mash filter, wherein the low temperature water outlet of the hot water storage device is connected with the low temperature water connection of the exhaust vapor condenser.

A method, and related apparatus, for producing beer from any types of grains includes activating phenomena of controlled hydro-dynamic cavitation during all the steps of the process, from mashing to hopping, and possibly after yeast inoculation. The present method and apparatus provide a number of advantages over traditional techniques, for example, avoiding the pre-crushing of the malts or the grains, thereby increasing the efficiency of saccharification and of starch extraction, and avoiding the boiling at equal efficiency of the hopping. Another advantage is the opportunity of causing the concentration of gluten to fall in the final product simply with controlled hydraulic processes through electromechanics, and of possibly extending fermentation.

A method, and related apparatus, for producing beer from any types of grains includes activating phenomena of controlled hydro-dynamic cavitation during all the steps of the process, from mashing to hopping, and possibly after yeast inoculation. The present method and apparatus provide a number of advantages over traditional techniques, for example, avoiding the pre-crushing of the malts or the grains, thereby increasing the efficiency of saccharification and of starch extraction, and avoiding the boiling at equal efficiency of the hopping. Another advantage is the opportunity of causing the concentration of gluten to fall in the final product simply with controlled hydraulic processes through electromechanics, and of possibly extending fermentation.

A automated beer-brewing system and method includes plural brewing containers, supply containers, and post-beer-brewing containers to bottle the brewed beer and to handle waste fluids and solids. Plural pipes couple the brewing containers to the group post-beer-brewing containers and beer-brewing containers. Plural brew-cycle control valves are coupled to each of the pipes, to locate all of the control valves in a central region of the system.

A automated beer-brewing system and method includes plural brewing containers, supply containers, and post-beer-brewing containers to bottle the brewed beer and to handle waste fluids and solids. Plural pipes couple the brewing containers to the group post-beer-brewing containers and beer-brewing containers. Plural brew-cycle control valves are coupled to each of the pipes, to locate all of the control valves in a central region of the system.

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.

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.

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.