A
5-l. round-bottomed flask, set up in a good
hood (Note
1), is fitted with a
three-holed rubber stopper that holds
two 250-cc. separatory funnels, A and B (Fig. 18). A small
funnel F (about 3–4 cm. in diameter) is suspended directly under the outlets of the two separatory funnels and is attached to the rubber stopper by a loop of stiff copper wire. The discharge tube of the funnel is bent in the shape of a U so that its end is about 1 cm. below the top of the funnel. In the third hole of the rubber stopper is inserted an
inclined glass tube, C, of about 10-mm. internal bore and approximately 50 cm. long. A
mercury safety vent, D, is sealed in the side of this tube. C acts as an
air condenser and leads to an
empty gas bottle, E, of about 250-cc. capacity and then to
three large U-tubes, G, H, and I, filled with anhydrous calcium chloride. The gas bottle and the U-tubes are contained in a
water bath, W, warmed to 30–40°. The last
calcium chloride tube is fitted with a
three-way glass stopcock so that the gaseous
anhydrous hydrogen cyanide may be used directly or diverted to an efficient condenser for liquefaction. The
condenser is a glass coil of 4–5 mm. bore and about 50 cm. long that is surrounded by ice (Note
2) contained in a percolator arrangement like that described on
p. 117.
Fig. 18.
One of the separatory funnels is filled with dilute
sulfuric acid prepared by the careful addition of
392 g. (213 cc., 4 moles) of concentrated sulfuric acid to 830 cc. of water. The other separatory funnel is filled with a solution of
203 g. (4 moles) of commercial sodium cyanide (about 96 per cent) dissolved in sufficient water to make 500 cc. of solution. Evolution of
hydrogen cyanide takes place on the simultaneous addition of the two solutions. Practically all the reaction occurs in the funnel, F, and the
sodium bisulfate solution continuously drains into the flask so that fresh solutions are always present. The solution in the funnel remains clear as long as sufficient
sulfuric acid is present. An excess of
sodium cyanide colors the solution yellow and leads to the formation of a muddy brown precipitate (Note
3). By adjusting the flow of solutions the rate of evolution is easily controlled, and the preparation requires no attention beyond that involved in the occasional replenishment of the solutions in the separatory funnels. The last part of the
hydrogen cyanide can be driven from the apparatus by boiling the bisulfate solution for a few minutes. The yield of acid melting at
− 15° to − 14.5° is
100–105 g. (
93–97 per cent of the theoretical amount) (Note
4) and (Note
5).