Glycerol - Definition, Manufacture, Uses and Properties

Glycerol.

Ball-and-stick model of glycerol
Glycerol or 1,2,3-propanetriol is the most important trihydric alcohol. It was formerly known as Glycerine. Glycerol is found in all-natural fats and oils as glycerol esters of long-chain carboxylic acids.



Manufacture. Glycerol is manufactured:


(1) From Fats and Oils.

Natural tits and fats are triesters of glycerol and long-chain carboxylic acids (mainly palmitic, stearic, and oleic acid). On hydrolysis with alkali, the fat and oils produce glycerol and the sails of the long-chain acids which are called soaps.

Glycerol

In the above equation, R is 9 to 17 carbons. The hydrolysis of fats and oils is carried originally for soap manufacture, and glycerol is obtained as a by-product. This is still a commercial source of glycerol.




Glycerol from Soap Manufacture. 

In soap manufacture, the fat is hydrolyzed by boiling with an alkali solution. The carboxylic acids produced by hydrolysis react with the alkali to form solid soap while the glycerol is left in the solution. The soap is filtered out. The filtrate is called Spent Lye.

Spent lye contains 4 to 6 per cent glycerol, unused alkali, soluble soaps, and suspended impurities. It is allowed to stand in a tank where most of the suspended impurities settle down. The clear solution is transferred to a new tank where it is first treated with HCL to neutralise excess alkali. It is then treated with alum (aluminium sulphate) and steam (Fig 16:2). The remaining excess alkali is precipitated as aluminium hydroxide and the soluble soaps are converted into insoluble aluminium soaps. These impurities are filtered out. The filtrate is next concentrated under vacuum when most of the sodium chloride separates out. This is filtered and the filtrate is treated with animal charcoal to remove coloured impurities. After filtration, it is again subjected to vacuum distillation. The glycerol thus obtained is 90 per cent pure. To obtain pure glycerol, it is redistilled under vacuum until distillate has a specific gravity of 26.


From Propane. 

Large quantities of glycerol are obtained as a by-product in the manufacture of soap. However, this supply is not sufficient. Today much of glycerol is manufactured from propene obtained by the catalytic cracking of petroleum. Following four steps are involved :

Step 1.

Propene is treated with Cl2 at 600C to give allyl chloride.

Step 2.

Allyl chloride is treated with dil. NaOH to give allyl alcohol.

Step 3.

Allyl alcohol is treated with dilute hypochlorous acid to give a chlorohydrin. The addition of HOCL to the carbon-carbon double bond takes place according to the Markovnikov rule.

Step 4.

The chlorohydrin is treated with dil. NaOH to yield glycerol.

Physical properties.


Glycerol is a colourless, odourless sweet-tasting and syrupy liquid, bp 200°C. it is non-toxic. Glycerol is soluble in water and ethanol, but insoluble in ether. It is hygroscopic, that is, it absorbs moisture from the air.

Chemical properties.

Glycerol molecule contains two primary -OH groups and one secondary -OH group. It undergoes many of the reactions to be expected of these types of alcohols. The carbon atoms in glycerol are indicated as αβ and α.

Uses.

Glycerol is nontoxic and an excellent humectant (moisture-retaining agent). It is used in bakery products, hand lotions, vanishing creams, shaving soaps and toothpaste s. Glycerol is used in the production of plastics, synthetic fibres, and surface coatings. It is used in the manufacture of explosives like Dynamite and Cordite.

Formula:  C3H8O3

Density:  1.26 g/cm³

Boiling point:  290 °C

IUPAC ID:  propane-1,2,3-triol

Molar mass:  92.09382 g/mol

Melting point:  17.8 °C




Glycerol - Definition, Manufacture, Uses and Properties Glycerol - Definition, Manufacture, Uses and Properties Reviewed by Genuine Chemistry on January 23, 2019 Rating: 5

No comments:

Powered by Blogger.