Ultraviolet irradiation of fluids for the purposes of disinfection, sterilization and modification of a target organic compound found within the fluids. The target compound in the fluids can have an absorption spectra with an ultraviolet wavelength ranging from 230 nm to 360 nm. The absorption spectra includes a first and second set of wavelengths corresponding to absorption peaks and absorption valleys in the absorption spectra, respectively. A-set of ultraviolet radiation sources irradiate the fluids. The set of ultraviolet radiation sources operate at a set of peak wavelengths ranging from 230 nm to 360 nm with a peak full width at half maximum that is less than 20 nm. The set of peak wavelengths are proximate to at least one wavelength in the second set of wavelengths corresponding to the absorption valleys in the absorption spectra with a variation of a full width half maximum of the absorption valley.

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.

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.

A compact beer brewing system (1) has vessels (2, 3) configured to perform mashing, lautering and boiling brewing stages applicable in small scale craft brewing operations. The compact and cost efficient brewing system easily, precisely and repeatably controls and improves critical brew processes involved in brewing and serving by including a bottom vessel (2) having an inner tun (28) configured to perform mashing and boiling stages, a top vessel (3) positioned above the bottom vessel (2) in fluid communication with the tun (28) and configured to perform lautering stage, and a pump (51) for moving fluid from the tun (28) to the top vessel (3). Preferably at least the bottom tun (28) and/or the top vessel (3) is/are substantially cylindrical, the diameter of the top vessel (3) is smaller than the diameter of the bottom tun (28) and the top vessel (3) is placed eccentrically over the bottom tun (28).

A system for brewing beer in small batches comprises a first heat exchanger and a second heat exchanger. The first heat exchanger delivers heated fluid into the second heat exchanger. A fluid-in line delivers cool fluid into the second heat exchanger. The second heat exchanger is configured to indirectly chill or heat brewing ingredients in a vessel.

A system for brewing beer in small batches comprises a first heat exchanger and a second heat exchanger. The first heat exchanger delivers heated fluid into the second heat exchanger. A fluid-in line delivers cool fluid into the second heat exchanger. The second heat exchanger is configured to indirectly chill or heat brewing ingredients in a vessel.

The present invention provides a process for treating a wort composition in a kettle, said method providing a significant energy saving compared to existing wort treatment processes. In particular, the process includes a hot-hold step for the wort, followed by gas sparging at elevated temperatures.

A user interface for a beer recipe creator may have a series of icons that may represent ingredients. A user may drag and drop or otherwise add the icons to containers on a display screen to add or remove ingredients to the recipe. With each added or removed ingredient, a set of descriptors may be updated. The descriptors may include numerical values of beer parameters as well as textual descriptions and visual descriptions. The system may allow a user to start with a desired beer style, and the parameters may show variances from the selected style. The system may generate an ingredients list, as well as a brewing recipe that may be transferred to a controller for a beer making machine. The system may adjust certain parameters that are controllable by the beer making machine to make flavor and other adjustments selected by a user.

A beer maker may include: a fermentation container having a beer brewing space, a thermoelectric module (or device) for heating or cooling inside of the housing, an ingredient supplying device, and a main channel connecting the ingredient supplying device and the beer brewing space to each other. Ingredients may be fermented in the fermentation vessel container, which is protected by a housing. Ingredients may be provided into the beer brewing space in a state that a lid is closed, a foreign substance may be minimized from being contained in the beer.

The invention relates to a method for the production of hulupones, in particular for the production of hulupones products, suitable for beer bittering, essentially free of compounds, typically formed as side-products during the lupulones oxidation, that can cause negative impact in terms of aroma, taste or haze upon brewing application. The invention also relates to hulupones products, suitable for beer bittering and obtainable by the method of the invention, essentially free of compounds with negative aroma, taste or haze impact upon addition of the hulupones products during the brewing process. The invention also relates to beer bittering with hulupones products, obtainable by the method of the invention, not causing an undesirable or unacceptable aroma, taste or haze impact in the bittered beer.