Stirrer Stirring

Ruhr-fass, n. churn (J/ to/.) dolly tub. -form, /. form or shape of stirrer, -frischen, n. (Metal.) puddling. -geschwindigkeit, /. velocity of stirring. -tUikchen, n. small stirring hook, -haken, m. stirring implement, rake, rabble, poker, -holz, n. wooden stirrer, stirring stick, paddle. 

Mixtures containing polystyrene resins should either be shaken or stirred with a mechanical stirrer. Stirring with a magnetic stir bar results in destruction of resin beads and the resulting debris can clog frits during filtrations. 

The construction of the experimental setup has been described earlier [7]. A standard quantity of ruthenium catalyst (0.20 g), 2(X) cm of substrate, 75 cm of doubly distilled water and 2.1 mmol of ZnS04-7H20 were introduced into the stainless-steel autoclave, equipped with baffle bars. After purging with hydrogen, the pressure was elevated to 3.5 MPa. When the desired reaction temperature (423 K) was reached, the total pressure was adjusted to 5.0 MPa. The benzene or toluene hydrogenation was started by switching on the stirrer (stirring speed 1500 rpm). 

In a 12 L, round-bottomed flask equipped wdth an overhead stirrer, stir a two-phase mixture of an ether solution of binaphthol dipentanoate (4 L, 0.71 mol, prepared from 203 g of racemic binaphthol) and an aqueous solution of sodium taurocholate (60 g, cmde grade in 4 L of 0.1 M phosphate buffer, pH 7.5) to form an opaque emulsion. Add bovine pancreas acetone powder (150 g), stopper the flask to minimize evaporation of ether and continue stirring slowly. The pH of the emulsion is measured occasionally and readjusted to 7.2 + 0.3... 

Place 80 g, of hydroxylamine sulphate (or 68-5 g. of the hydrochloride), 25 g. of hydrated sodium acetate, and 100 ml. of water in a 500 ml. flask fitted with a stirrer and a reflux water-condenser, and heat the stirred solution to 55-60°. Run in 35 g (42 nil,) of -hexyl methyl ketone, and continue the heating and vigorous stirring for ij hours. (The mixture can conveniently be set aside overnight after this stage.) Extract the oily oxime from the cold mixture twice with ether. Wash the united ethereal extract once with a small quantity of water, and dry it with sodium sulphate. Then distil off the ether from the filtered extract, preferably using a distillation flask of type shown in Fig. 41 (p. 65) and of ca, 50 ml, capacity, the extract being run in as fast as the ether distils, and then fractionally distil the oxime at water-pump pressure. Collect the liquid ketoxime, b.p. 110-111713 mm. Yield, 30-32 g. 

Assemble a 250 ml. three-necked flask, fitted with a stirrer, a reflux condenser and a dropping-funnel, as in Fig. 22(A) and (j), p. 43, or Fig. 23(c), p. 46 (or a two-necked flask, with the funnel fitted by a grooved cork (p. 255) to the top of the condenser). Place 40 ml. of ethanol in the flask, and then add 2-3 g. of sodium cut into small pieces. When all the sodium has dissolved, heat the stirred solution on the water-bath, and run in from the funnel 17 g. (17 ml.) of ethyl malonate and then (more slowly) io-2 g. (12 ml.) of mesityl oxide, the reaction-mixture meanwhile forming a thick slurry. Boil the stirred mixture under reflux for i hour, and then add a solution of 10 g. of sodium hydroxide in 50 ml. of water, and continue boiling the pale honey-coloured solution for ij hours more. 

A 1500 ml. flask is fitted (preferably by means of a three-necked adaptor) with a rubber-sleeved or mercury-sealed stirrer (Fig. 20, p. 39), a reflux water-condenser, and a dropping-funnel cf. Fig. 23(c), p. 45, in which only a two-necked adaptor is shown or Fig. 23(G)). The dried zinc powder (20 g.) is placed in the flask, and a solution of 28 ml. of ethyl bromoacetate and 32 ml. of benzaldehyde in 40 ml. of dry benzene containing 5 ml. of dry ether is placed in the dropping-funnel. Approximately 10 ml. of this solution is run on to the zinc powder, and the mixture allowed to remain unstirred until (usually within a few minutes) a vigorous reaction occurs. (If no reaction occurs, warm the mixture on the water-bath until the reaction starts.) The stirrer is now started, and the rest of the solution allowed to run in drop-wise over a period of about 30 minutes so that the initial reaction is steadily maintained. The flask is then heated on a water-bath for 30 minutes with continuous stirring, and is then cooled in an ice-water bath. The well-stirred product is then hydrolysed by the addition of 120 ml. of 10% sulphuric acid. The mixture is transferred to a separating-funnel, the lower aqueous layer discarded, and the upper benzene layer then... 

Fit a three necked 250 ml. flask with a central rubber-sleeved or mercury-sealed stirrer, c/. Fig. 23(c), p. 45, where only two necks are shown, and with a thermometer the bulb of which reaches as near the bottom of the flask as the stirrer allows the third neck will carry at first a dropping-funnel and later a reflux condenser. Place 20 g. (19-5 ml.) of ethyl acetoacetate and 45 ml. of glacial acetic acid in the flask and by ice-water cooling adjust the temperature of the stirred mixture to 5 -7° maintain this temperature whilst adding a solution of 5 4 g. of sodium nitrite in 8 ml. of water slowly from the dropping-funnel during 15 minutes. Continue the stirring for 20-30 minutes, and then... 

Fit a 250 ml. three-necked flask with a stirrer, a reflux condenser and a dropping-funnel. (Alternatively, use a two-necked flask, with the dropping-funnel fitted by a grooved cork into the condenser.) Place 15 g. of powdered thiourea and 40 ml. of water in the flask and stir the mixture whilst 18 5 g. (16 ml.) of chloroacetone are added dropwise over a period of 20 minutes the thiourea will dissolve and the temperature of the mixture... 

Now add the diazonium solution slowly from a dropping-funnel to the vigorously-stirred arsenite solution, keeping the temperature of the latter at 5 7°. The frothing caused by the evolution of nitrogen will probably be dispersed by the stirrer if not, the addition of 1-2 ml. of ether, preferably in a fine jet from a wash-bottle, will cause it to subside. 

Mercury-sealed stirrers are used in the following operations (1) simultaneous stirring and refluxing of a reaction mixture (2) stirring the contents of a closed vessel (3) agitation with prevention of the escape of a gas or vapour and (4) stirring in an inert atmosphere, such as... 

This stirrer is not dependable for stirring operations lasting several hours the rubber tubing may stick to the shaft sind may also be attsu ked by the orgsinic vapours causing it to swell and allow the escape of vapours. 

A common operation in practical organic chemistry is for stirring, refluxing, and addition of a liquid from a dropping funnel to be carri on simultaneously. The most convenient apparatus for this purpose is a three-necked flask, fitted as in Fig. 11, 7, 11, a. If a three-necked flask is not available, the three-way adapter inserted into a bolt-head flask (Fig. 77, 7, 11, 6) may be used. A further simplification, suitable for elementary students, is to employ a two-way adapter as in Fig. 77, 7, 11, c the stirrer passes through a closely-fitting glass sleeve which is extended... 

Cuprous cyanide solution. The most satisfactory method is to dissolve the cuprous cyanide (1 mol) in a solution of technical sodium cyanide (2 5-2-6 mols in 600 ml. of water). If it is desired to avoid the preparation of solid cuprous cyanide, the following procedure may be adopted. Cuprous chloride, prepared from 125 g. of copper sulphate crystals as described under 1 above, is suspended in 200 ml. of water contained in a 1-litre round-bottomed flask, which is fitted with a mechanical stirrer. A solution of 65 g. of technical sodium cyanide (96-98 per cent.) in 100 ml. of water is added and the mixture is stirred. The cuprous chloride passes into solution with considerable evolution of heat. As the cuprous cyanide is usually emplo3 ed in some modification of the diazo reaction, it is usual to cool the resulting solution in ice. 

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