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Acid feed

Urea is also used as feed supplement for mminants, where it assists in the utilization of protein. Urea is one of the raw materials for urea—formaldehyde resins. Urea (with ammonia) pyrolyzes at high temperature and pressure to form melamine plastics (see also Cyanamides). Urea is used in the preparation of lysine, an amino acid widely used in poultry feed (see Amino acids Feeds and feed additives, petfoods). It also is used in some pesticides. [Pg.310]

The principal reactions are reversible and a mixture of products and reactants is found in the cmde sulfate. High propylene pressure, high sulfuric acid concentration, and low temperature shift the reaction toward diisopropyl sulfate. However, the reaction rate slows as products are formed, and practical reactors operate by using excess sulfuric acid. As the water content in the sulfuric acid feed is increased, more of the hydrolysis reaction (Step 2) occurs in the main reactor. At water concentrations near 20%, diisopropyl sulfate is not found in the reaction mixture. However, efforts to separate the isopropyl alcohol from the sulfuric acid suggest that it may be partially present in an ionic form (56,57). [Pg.107]

The process requires water vapor removal from the generator to be balanced with the water introduced with the chloric acid feed. Significantly greater chlorine dioxide generator capacity is achievable than using the older design generators. [Pg.483]

Visually inspect acid feed equipment such as pumps on a regular basis. [Pg.171]

An example where reactant concentration is solely governed by corrosion considerations is in the production of concentrated nitric acid by dehydration of weak nitric acid with concentrated sulphuric acid. The ratio of HN0j H2S04 acid feeds is determined by the need to keep the waste sulphuric acid at > 70 Vo at which concentrations it can be transported in cast-iron pipes and stored after cooling in carbon-steel tanks. [Pg.16]

Tsuge, T., Shimoda, M, Ishizaki, A., 1999. Optimization of L-Lactic acid feeding for the... [Pg.59]

Macrolide aggregation pheromones produced by male cucujid beetles are derived from fatty acids. Feeding experiments with labeled oleic, linoleic, and palmitic acids indicate incorporation into the macrolide pheromone component [ 117 ]. The biosynthesis of another group of beetle pheromones, the lactones, involves fatty acid biosynthetic pathways. Japonilure and buibuilactone biosynthesized by the female scarab, Anomalajaponica, involves A9 desaturation of 16 and 18 carbon fatty acids to produce Z9-16 CoA and Z9-18 CoA,hydroxylation at carbon 8 followed by two rounds of limited chain shortening and cyclization to the lactone [118]. The hydroxylation step appears to be stereospecific [118]. [Pg.117]

After extensive research and several tests, the option selected was recycling hypochlorite to the feed brine of the electrolysis cells. For this purpose, hypochlorite feed pipes were manufactured and the hydrochloric acid feed capacity to the brine degassing tanks was enlarged. [Pg.192]

The citric acid cycle is at the heart of aerobic cellular metabolism, or respiration. This is true of both prokaryotic and eukaryotic organisms, of plants and animals, of organisms large and small. Here is the main point. On the one hand, the small molecule products of catabolism of carbohydrates, lipids, and amino acids feed into the citric acid cycle. There they are converted to the ultimate end products of catabolism, carbon dioxide and water. On the other hand, the molecules of the citric acid cycle are intermediates for carbohydrate, lipid, and amino acid synthesis. Thus, the citric acid cycle is said to be amphibolic, involved in both catabolism and anabolism. It is a sink for the products of degradation of carbohydrates, lipids, and proteins and a source of building blocks for them as well. [Pg.230]

Solvent Extraction from Acid Feed Solutions... [Pg.613]

Apparently the acceleration of de novo purine biosynthesis by orotic acid results from a release of feedback inhibition imposed by hepatic purine nucleotides. In a related study, it was found that orotic acid feeding can prevent hyperlipaemia, which normally follows the administration of Triton WR-1339, a surface active agent [152]. The influence of orotic acid on lipid metabolism can be readily shown by the fact that depression of serum lipoproteins and milk production were observed in lactating goats when an aqueous suspension of orotic acid was administered orally [164]. [Pg.289]

Calcium sulfate crystals were precipitated in a Continuous Mixed Suspension Mixed Product Removal (CMSMPR) crystallizer by mixing of calcium phosphate and sulfuric acid feed streams. The formed calcium sulfate hydrate (anhydrite, hemihydrate and dihydrate) mainly depends on the temperature and the solution composition. The uptake of cadmium and phosphate ions in these hydrates has been studied as a function of residence time and solution composition. In anhydrite, also the incorporation of other metal ions has been investigated. The uptake was found to be a function of both thermodynamics and kinetics. [Pg.381]

Amino acid feed additive Biolys L-lysine Degussa, Germany... [Pg.111]

Various experiments in Vanilla plant cell cultures, however, gave different results [14-18, 30, 51]. This might be due to the fact that different biosynthetic pathways operate in the beans and in the cell culture. In fact most of the work in cell cultures showed only conversion of non-glucosylated products. Ferulic acid feeding resulted in increased vanillin levels. The fact that the V. planifolia cell cultures do not produce vanillin in any significant amount means that the results from studies using vanilla cell cultures for elucidation of the pathway should be considered with caution. Finally, it cannot be excluded that different pathways may contribute to the vanillin production in the beans. Scheme 9.1 shows that vanillin can be formed through different ways in a complex network of compounds. [Pg.206]

For constant molar vapor flow in the column system, the vapor flow rate leaving the reboiler, per part of weak acid feed, is 0.6 (1 + R2) 18/63 and the weight fraction of Mg(NC>3)2 in the magnesium nitrate solution leaving the column base... [Pg.146]

Figure 6. Concentration of boron in the permeate (solid squares) as a function of permeate volume as the 1.63 mM boric acid feed (pH 9) was diafiltered through the holding cell containing 100 ml water and 4.755 g GP3 dendrimer. The permeate pH rose from 5.02 at the beginning of the run to 7.75 at the end. Model parameters Rg, 88.5 A K, 6300 K2,105 Mw, 55471 fp, 0.024. Figure 6. Concentration of boron in the permeate (solid squares) as a function of permeate volume as the 1.63 mM boric acid feed (pH 9) was diafiltered through the holding cell containing 100 ml water and 4.755 g GP3 dendrimer. The permeate pH rose from 5.02 at the beginning of the run to 7.75 at the end. Model parameters Rg, 88.5 A K, 6300 K2,105 Mw, 55471 fp, 0.024.
Sulfinic acid - [FEEDS AND FEED ADDITIVES - PET FOODS] (Vol 10)... [Pg.943]

See other pages where Acid feed is mentioned: [Pg.448]    [Pg.235]    [Pg.345]    [Pg.366]    [Pg.366]    [Pg.92]    [Pg.378]    [Pg.1323]    [Pg.172]    [Pg.172]    [Pg.8]    [Pg.274]    [Pg.102]    [Pg.198]    [Pg.146]    [Pg.168]    [Pg.784]    [Pg.82]    [Pg.270]    [Pg.478]    [Pg.552]    [Pg.34]    [Pg.70]    [Pg.95]    [Pg.324]    [Pg.410]    [Pg.410]    [Pg.265]    [Pg.143]    [Pg.317]    [Pg.108]    [Pg.141]    [Pg.319]   
See also in sourсe #XX -- [ Pg.189 ]

See also in sourсe #XX -- [ Pg.189 ]



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