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Residual sodium carbonate

Lime Soda. Process. Lime (CaO) reacts with a dilute (10—14%), hot (100°C) soda ash solution in a series of agitated tanks producing caustic and calcium carbonate. Although dilute alkaH solutions increase the conversion, the reaction does not go to completion and, in practice, only about 90% of the stoichiometric amount of lime is added. In this manner the lime is all converted to calcium carbonate and about 10% of the feed alkaH remains. The resulting slurry is sent to a clarifier where the calcium carbonate is removed, then washed to recover the residual alkaH. The clean calcium carbonate is then calcined to lime and recycled while the dilute caustic—soda ash solution is sent to evaporators and concentrated. The concentration process forces precipitation of the residual sodium carbonate from the caustic solution the ash is then removed by centrifugation and recycled. Caustic soda made by this process is comparable to the current electrolytic diaphragm ceU product. [Pg.527]

Whether for a class demonstration, a practical joke, or perhaps a clandestine activity, disappearing ink is a fascinating substance. What is the secret to its action One formulation of disappearing ink contains a common acid-base indicator, that is, a substance that by its color shows the acid or basic nature of a solution. One acid-base indicator that shifts from a colorless hue under acidic conditions to a deep blue color in alkaline solutions is thymolphthalein. If the indicator starts off in a basic solution, perhaps containing sodium hydroxide, the typical blue color of an ink is perceived. How does the ink color disappear This behavior is dependent upon the contact of the ink with air. Over time, carbon dioxide in the air combines with the sodium hydroxide in the ink solution to form a less basic substance, sodium carbonate. The carbon dioxide also combines with water in the ink to form carbonic acid. The indicator solution responds to the production of acid and returns to its colorless acid form. A white residue (sodium carbonate) remains as the ink dries. [Pg.74]

Alkalinity and hardness (dissolved Ca24 and Mg2+, Box 12-3) are important characteristics of irrigation water. Alkalinity in excess of the Ca2+ + Mg2+ content is called residual sodium carbonate. " Water with a residual sodium carbonate content equivalent to 2.5 mmol H+/L is not suitable for irrigation. Residual sodium carbonate between 1.25 and 2.5 mmol H+/L is marginal, whereas si.25 mmol H+/L is suitable for irrigation. [Pg.209]

MEASURES OF SALINITY AND ALKALINITY 8.2a. The Residual Sodium Carbonate (RSC) Value... [Pg.278]

The alkalinity of water is measured as the residual sodium carbonate (RSC) value,... [Pg.278]

Early workers used the residual sodium carbonate (RSC) to predict the tendency of calcium carbonate to precipitate from high-bicarbonate waters and thus create a sodium hazard. The RSC was defined as... [Pg.288]

If the irrigation water of Problem 5 has a pH of 7.8, what is the residual sodium carbonate value To what extent would the water be regarded as hazardous based on this criterion ... [Pg.302]

An evaluation/confirmation of the achievable performances on a semi-industrial scale (for the reactor block treatment) will be carried out under the TRIPOT test on a sodium loop at the CEA Cadarache. This is a carbonation test on a model representing the discontinuities (retentions, accessibility to carbonation fluid) encountered in the reactor block internal structures. This test could take place during 2004. After draining of the reactor block and before the residual sodium carbonation operation, the retentions will be treated in order to eliminate them or reduce the thickness. [Pg.195]

This reaction does not go to completion, therefore only 90% of the stoichiometric amount of lime is added. The calcium carbonate is removed, calcined to reform lime, and recycled. The dilute sodium hydroxide solution is concentrated by evaporation. This causes most of the residual sodium carbonate to precipitate so that it can be removed. ... [Pg.440]

In vacuum reduction experiment, lithium carbonate(Li2COs a 99.0%), calcium oxide(CaO a 98%), alumina(Al203 a 98%) and aluminum power (A1 a 99%)are needed. In the leaching of reduchon residue, sodium carbonate and sodium hydroxide solution are needed. [Pg.12]

At the 22 MWg demonstration of the dry soda injection process at the Public Service Company of Colorado Cameo Unit 1 (Muzio and Sonnichsen, 1982), both nahcolite and trona were used as sorbents and both performed satisfactorily. Pure sodium carbonate was found to provide very limited SO2 removal (nominally 10%). It was concluded that nahcolite and trona are effective because they thermally decompose to release CO2 and H2O, which greatly enhances the porosity and reactive surface area of the residual sodium carbonate. The decomposition of trona occurs at significant rates above 200°F while nahcolite requites temperatures above about 275°F for decomposition. Once thermal decomposition is initiated, SO2 begins to react with Na2C03 according to the following reaction ... [Pg.625]

Add 1 ml. of the alcohol-free ether to 0-1-0-15 g. of finely-powdered anhydrous zinc chloride and 0 5 g. of pure 3 5-dinitrobenzoyl chloride (Section 111,27,1) contained in a test-tube attach a small water condenser and reflux gently for 1 hour. Treat the reaction product with 10 ml. of 1-5N sodium carbonate solution, heat and stir the mixture for 1 minute upon a boiling water bath, allow to cool, and filter at the pump. Wash the precipitate with 5 ml. of 1 5N sodium carbonate solution and twice with 6 ml. of ether. Dry on a porous tile or upon a pad of filter paper. Transfer the crude ester to a test-tube and boil it with 10 ml. of chloroform or carbon tetrachloride filter the hot solution, if necessary. If the ester does not separate on cooling, evaporate to dryness on a water bath, and recrystallise the residue from 2-3 ml. of either of the above solvents. Determine the melting point of the resulting 3 5 dinitro benzoate (Section 111,27). [Pg.316]

Dissolve 2 drops of concentrated sulphuric acid in 2 ml. of the ester and add 1 - 5 g. of 3 5-dinitrobenzoic acid. If the b.p. of the ester is below 150°, refiux the mixture gently if the b.p. is above 150° heat the mixture, with frequent shaking at first, in an oil bath at about 150°. If the 3 5-dinitrobenzoic acid dissolves within 15 minutes, heat the mixture for 30 minutes, otherwise 60 minutes heating is required. Allow the reaction mixture to cool, dissolve it in 25 ml. of ether, and extract thoroughly with 5 per cent, sodium carbonate solution (ca. 25 ml.). Wash the ethereal solution with water, and remove the ether. Dissolve the residue (which is usually an oil) in 5 ml. of hot alcohol, add hot water cautiously until the 3 5-dinitrobenzoate commences to separate, cool and stir. Recrystallise the derivative from dilute alcohol the yield is... [Pg.393]

The following is a modification of the process described and gives quite satisfactory results. Wash the crude mixture of benzonitrile and dibromopentane with sodium carbonate solution until the latter remains alkaline, and then with water. Distil it under reduced pressure and collect the fraction boiling up to 120°/18 mm. Dissolve this in twice its volume of light petroleum, b.p. 40-60°, which has previously been shaken with small volumes of concentrated sulphuric acid until the acid remains colourless. Shake the solution with 6 per cent, of its volume of concentrated sulphuric acid, allow to settle, and run ofi the sulphuric acid layer repeat the extraction until the acid is colourless or almost colourless. Wash successively with water, sodium carbonate solution and water, dry over anhydrous calcium chloride or calcium sulphate, and distil off the solvent. Distil the residue under diminished pressure and collect the 1 6-dibromopentane at 98- 100°/13 mm. [Pg.493]

In a 500 ml. flask, fitted with a reflux condenser, place 53 g. of 1-chloro-methylnaphthalene (Section IV.23), 84 g, of hexamethylenetetramine and 250 ml. of 1 1 acetic acid [CAUTION 1-Chloromethylnaphtha-lene and, to a lesser degree, a-naphthaldehyde have lachrymatory and vesicant properties adequate precautions should therefore be taken to avoid contact with these substances.] Heat the mixture under reflux for 2 hours it becomes homogeneous after about 15 minutes and then an oil commences to separate. Add 100 ml. of concentrated hydrochloric acid and reflux for a further 15 minutes this will hydrolyse any SchifiF s bases which may be formed from amine and aldehyde present and will also convert any amines into the ether-insoluble hydrochlorides. Cool, and extract the mixture with 150 ml. of ether. Wash the ether layer with three 50 ml. portions of water, then cautiously with 50 ml. of 10 per cent, sodium carbonate solution, followed by 50 ml. of water. Dry the ethereal solution with anhydrous magnesium sulphate, remove the ether by distillation on a steam bath, and distil the residue under reduced pressure. Collect the a-naphthaldehyde at 160-162718 mm. the yield is 38 g. [Pg.700]

Add dilute sulphuric acid, with stirring, to the cold alkahne solution until the solution is acid to htmus or Congo red paper and the acid, if a solid, commences to separate as a faint permanent precipitate. Now add dilute sodium carbonate solution until the solution is alkahne (litmus paper) and any precipitate has completely redissolved. Extract the clear solution twice with ether evaporate or distil the ether from the ethereal solution on a water bath CAUTION no flames may be near) and identify the residual phenol as under 1. Remove the dissolved ether from the aqueous solution by boiling, acidify with dilute sulphuric acid and identify the organic acid present (see Sections 111,85 and IV, 175). [Pg.786]

Method 1. Equip a 1 litre three-necked flask (or bolt-head flask) with a separatory funnel, a mechanical stirrer (Fig. II, 7, 10), a thermometer (with bulb within 2 cm. of the bottom) and an exit tube leading to a gas absorption device (Fig. II, 8, 1, c). Place 700 g. (400 ml.) of chloro-sulphonic acid in the flask and add slowly, with stirring, 156 g. (176 ml.) of pure benzene (1) maintain the temperature between 20° and 25° by immersing the flask in cold water, if necessary. After the addition is complete (about 2 5 hours), stir the mixture for 1 hour, and then pour it on to 1500 g. of crushed ice. Add 200 ml. of carbon tetrachloride, stir, and separate the oil as soon as possible (otherwise appreciable hydrolysis occurs) extract the aqueous layer with 100 ml. of carbon tetrachloride. Wash the combined extracts with dilute sodium carbonate solution, distil off most of the solvent under atmospheric pressure (2), and distil the residue under reduced pressure. Collect the benzenesulphonyl chloride at 118-120°/15 mm. it solidifies to a colourless sohd, m.p. 13-14°, when cooled in ice. The yield is 270 g. A small amount (10-20 g.) of diphen3 lsulphone, b.p. 225°/10 mm., m.p. 128°, remains in the flask. [Pg.822]

See other pages where Residual sodium carbonate is mentioned: [Pg.222]    [Pg.373]    [Pg.1143]    [Pg.222]    [Pg.373]    [Pg.1143]    [Pg.158]    [Pg.237]    [Pg.245]    [Pg.273]    [Pg.326]    [Pg.287]    [Pg.327]    [Pg.355]    [Pg.433]    [Pg.446]    [Pg.480]    [Pg.568]    [Pg.569]    [Pg.588]    [Pg.643]    [Pg.650]    [Pg.694]    [Pg.702]    [Pg.712]    [Pg.712]    [Pg.719]    [Pg.739]    [Pg.767]    [Pg.768]    [Pg.776]    [Pg.785]   
See also in sourсe #XX -- [ Pg.278 , Pg.303 ]

See also in sourсe #XX -- [ Pg.288 ]



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Carbon residue

Carbonized residue

Residual carbon

Sodium carbonate

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