Caffeine-adsorbing materials, caffeine-adsorbing systems, and decaffeination system suitable for removing caffeine from a solution; methods for removing caffeine from a solution; and methods of making the caffeine-adsorbing materials are described.

Caffeine-adsorbing materials, caffeine-adsorbing systems, and decaffeination system suitable for removing caffeine from a solution; methods for removing caffeine from a solution; and methods of making the caffeine-adsorbing materials are described.

The disclosure provides a method for selectively removing sulfites, for example bisulfite anionic species, from a beverage comprising free sulfite by providing an effective amount of a non-ionic, solid phase material and contacting the beverage with the solid phase material thereby sequestering the free sulfite on the non-ionic, solid phase material and providing a beverage having a reduced amount of free sulfite that otherwise maintains the general chemical composition with which it started. The disclosure further provides a device for selectively removing sulfite from a beverage comprising a container for receiving a beverage comprising free sulfite, said container enclosing a non-ionic, solid phase material capable of sequestering free sulfite, and a modular apparatus comprising a sulfite capture module and optionally a sediment filter module or an aeration module. Optionally, the non-ionic solid phase material is food-safe.

The disclosure provides a method for selectively removing sulfites, for example bisulfite anionic species, from a beverage comprising free sulfite by providing an effective amount of a non-ionic, solid phase material and contacting the beverage with the solid phase material thereby sequestering the free sulfite on the non-ionic, solid phase material and providing a beverage having a reduced amount of free sulfite that otherwise maintains the general chemical composition with which it started. The disclosure further provides a device for selectively removing sulfite from a beverage comprising a container for receiving a beverage comprising free sulfite, said container enclosing a non-ionic, solid phase material capable of sequestering free sulfite, and a modular apparatus comprising a sulfite capture module and optionally a sediment filter module or an aeration module. Optionally, the non-ionic solid phase material is food-safe.

The present invention relates to a method for producing functionally improved carbolime from carbolime, and also functionally improved carbolime, which can be produced according to the inventive method, and the use of functionally improved carbolime as filtering aid, as filler, as lime fertilizer or as adsorbent for the adsorption of dyes.

The present invention relates to a method for producing functionally improved carbolime from carbolime, and also functionally improved carbolime, which can be produced according to the inventive method, and the use of functionally improved carbolime as filtering aid, as filler, as lime fertilizer or as adsorbent for the adsorption of dyes.

The present invention relates to a method for separating metal ions from a liquid, which method comprises contacting liquid comprising metal ions with non-functionalized cellulose, adsorbing the metal ions to the cellulose, and separating the liquid from the cellulose, wherein the liquid is an essential oil.

A composite filter aid may include acid-washed diatomaceous earth and a low extractable metal mineral. A method for making a composite material may include blending an acid-washed diatomaceous earth and a low extractable metal mineral, adding a binder to the blended diatomaceous earth and low extractable metal mineral, and forming the composite material from the acid-washed diatomaceous earth, the low extractable metal mineral, and the binder. A method for filtering a liquid may include providing a liquid for filtering and filtering the liquid through a composite filter aid that includes an acid-washed diatomaceous earth and a low extractable metal mineral.

A composite filter aid may include acid-washed diatomaceous earth and a low extractable metal mineral. A method for making a composite material may include blending an acid-washed diatomaceous earth and a low extractable metal mineral, adding a binder to the blended diatomaceous earth and low extractable metal mineral, and forming the composite material from the acid-washed diatomaceous earth, the low extractable metal mineral, and the binder. A method for filtering a liquid may include providing a liquid for filtering and filtering the liquid through a composite filter aid that includes an acid-washed diatomaceous earth and a low extractable metal mineral.

Disclosed is a process for enriching silicate content in drinking water that includes separating raw water via reverse osmosis into a permeate comprising demineralised raw water and a retentate comprising mineral enriched raw water. The permeate is mixed with a water glass solution comprising sodium silicate and/or potassium silicate. An ion exchange process is used to reduce the concentration of sodium and/or potassium ions in at least part of the mixture. At least part of the retentate is supplied to the mixture after reducing the concentration of sodium and/or potassium ions to provide a silicate-enriched drinking water. Also disclosed is an apparatus for producing a drinking water enriched with silicate. The apparatus includes a reverse osmosis unit, a mixing unit, an ion exchanger, and a feed unit for feeding at least part of the retentate to the mixture after reducing the concentration of sodium and/or potassium ions.