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Wine vinegar

Distinction between Fermentation Vinegar and Wood Vinegar. -"Wine vinegar may be characterised by its special aroma, by thd presence... [Pg.226]

Malt vinegar. Wine vinegar. Vinegar from alcohol. 203... [Pg.232]

Vinegar, wine, soft drinks, beer, orange juice, pickles... [Pg.84]

Blackberry, mango, chocolate, raspberry, vinegar, wine... [Pg.768]

Other fermented foods which also may be good sources of glucose tolerance factor are wine, apple cider, cider vinegar, wine vinegar, root beers, yeast-leavened whole grain breads, pickles, summer sausages, cheeses and their derivatives, and sauerkraut. [Pg.208]

Until the late nineteenth century, all acetic acid was derived from the classical process of sugar fermentation to ethyl alcohol followed by a second-stage microbial oxidation to acetic acid. The dilute solution of acetic acid produced by microbial metabolism is called vinegar. Wine souring leading to a variety of vinegars has been known as long as the... [Pg.5]

Fig. 1. An amplified outline scheme of the making of various wiaes, alternative products, by-products, and associated wastes (23). Ovals = raw materials, sources rectangles = wines hexagon = alternative products (decreasing wine yield) diamond = wastes. To avoid some complexities, eg, all the wine vinegar and all carbonic maceration are indicated as red. This is usual, but not necessarily tme. Similarly, malolactic fermentation is desired in some white wines. FW = finished wine and always involves clarification and stabilization, as in 8, 11, 12, 13, 14, 15, 33, 34, followed by 39, 41, 42. It may or may not include maturation (38) or botde age (40), as indicated for usual styles. Stillage and lees may be treated to recover potassium bitartrate as a by-product. Pomace may also yield red pigment, seed oil, seed tannin, and wine spidts as by-products. Sweet wines are the result of either arresting fermentation at an incomplete stage (by fortification, refrigeration, or other means of yeast inactivation) or addition of juice or concentrate. Fig. 1. An amplified outline scheme of the making of various wiaes, alternative products, by-products, and associated wastes (23). Ovals = raw materials, sources rectangles = wines hexagon = alternative products (decreasing wine yield) diamond = wastes. To avoid some complexities, eg, all the wine vinegar and all carbonic maceration are indicated as red. This is usual, but not necessarily tme. Similarly, malolactic fermentation is desired in some white wines. FW = finished wine and always involves clarification and stabilization, as in 8, 11, 12, 13, 14, 15, 33, 34, followed by 39, 41, 42. It may or may not include maturation (38) or botde age (40), as indicated for usual styles. Stillage and lees may be treated to recover potassium bitartrate as a by-product. Pomace may also yield red pigment, seed oil, seed tannin, and wine spidts as by-products. Sweet wines are the result of either arresting fermentation at an incomplete stage (by fortification, refrigeration, or other means of yeast inactivation) or addition of juice or concentrate.
Maturation is conducted in closed, full containers to prevent oxidation and aerobic growth of microorganisms. Etee air contact with low alcohol wine soon leads to vinegar. Except for those sherry types already mentioned, wines ate exposed to air minimally and temporarily. During transfers incident to bulk storage and processing, some air exposure is almost inevitable, mote in total the longer the wine is held. In the cases of white and pink table wines, it is ordinarily as neat zero as possible, and stainless steel or other impermeable containers, inert gas headspace, etc ate employed. Red wines withstand and even benefit from small but repeated exposures to air. [Pg.374]

Primitive people very likely encountered vinegar-like Hquids in hoUows in rocks or downed timber into which berries or fmit had fallen. Wild yeasts and bacteria would convert the natural sugars to alcohol and acetic acid. Later, when eady peoples had learned to make wines and beers, they certainly would have found that these Hquids, unprotected from air, would turn to vinegar. One can postulate that such eady vinegars were frequendy sweet, because the fmit sugars would have been acted on simultaneously by both bacteria and yeast. Only since the middle 1800s has it been known that yeast and bacteria are the cause of fermentation and vinegar formation. [Pg.408]

Freeze Crystallization. Freezing may be used to form pure ice crystals, which are then removed from the slurry by screens sized to pass the fine sohds but to catch the crystals and leave behind a more concentrated slurry. The process has been considered mostly for solutions, not suspensions. However, freeze crystallization has been tested for concentrating orange juice where sohds are present (see Fruit juices). Commercial apphcations include fmit juices, coffee, beer, wine (qv), and vinegar (qv). A test on milk was begun in 1989 (123). Freeze crystallization has concentrated pulp and paper black hquor from 6% to 30% dissolved sohds and showed energy savings of over 75% compared with multiple-effect evaporation. Only 35—46 kJ/kg (15—20 Btu/lb) of water removed was consumed in the process (124). [Pg.25]

Many carboxylic acids were first isolated from natural sources and were given names based on their origin. Fonnic acid (Latin formica, meaning ant ) was obtained by distilling ants. Since ancient times acetic acid (Latin acetum, for vinegar ) has been known to be present in wine that has turned sour. Butyric acid (Latin butyrum, meaning butter ) contributes to the odor of both rancid butter and ginkgo benies, and lactic acid (Latin lac, for milk ) has been isolated from sour milk. [Pg.806]


See other pages where Wine vinegar is mentioned: [Pg.309]    [Pg.1]    [Pg.98]    [Pg.122]    [Pg.142]    [Pg.266]    [Pg.208]    [Pg.319]    [Pg.51]    [Pg.12]    [Pg.1060]    [Pg.954]    [Pg.973]    [Pg.1186]    [Pg.619]    [Pg.309]    [Pg.1]    [Pg.98]    [Pg.122]    [Pg.142]    [Pg.266]    [Pg.208]    [Pg.319]    [Pg.51]    [Pg.12]    [Pg.1060]    [Pg.954]    [Pg.973]    [Pg.1186]    [Pg.619]    [Pg.419]    [Pg.4]    [Pg.806]    [Pg.370]    [Pg.177]    [Pg.443]    [Pg.309]    [Pg.538]    [Pg.52]    [Pg.403]    [Pg.407]    [Pg.407]    [Pg.407]    [Pg.408]    [Pg.408]    [Pg.408]    [Pg.409]    [Pg.409]    [Pg.409]    [Pg.410]    [Pg.410]    [Pg.390]    [Pg.449]    [Pg.4]   
See also in sourсe #XX -- [ Pg.302 ]




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