Module: 2 Lecture: 5 ACETIC ACID
Transcription
Module:2 Lecture:5 Acetic acid Dr. N. K. Patel Module: 2 Lecture: 5 ACETIC ACID INTRODUCTION Acetic acid, CH3COOH is an organic compound which also written as CH3CO2H or C2H4O2. It is a colourless liquid in undiluted form is called as glacial acetic acid. Andreas Libavius in the sixteenth century described a procedure for preparation of glacial acetic acid through the dry distillation of certain metal acetates like copper (II) acetate and compared the produced glacial acetic acid with vinegar. The presence of water in vinegar has such a profound effect on acetic acid's properties that for centuries chemists believed that glacial acetic acid and the acid found in vinegar were two different substances. Later on Pierre Adet proved that both are same. The very dilute form of acetic acid (8 – 10%) is known as vinegar and has a distinctive sour taste and pungent smell. Besides its production as household vinegar, it is mainly produced as a precursor to polyvinyl acetate and cellulose acetate. Although it is classified as a weak acid, while concentrated acetic acid is corrosive to the skin. Due to the global present of acetic acid producing bacteria via air oxidation of beer and wine vinegar was first known to the society. In the 3rd century BC, Theophrastus described how vinegar acted on metals to produce pigments useful in art, including white lead (lead carbonate) and verdigris, a green mixture of copper salts including copper (II) acetate. Ancient Romans boiled soured wine in lead pots producing lead acetate rich highly sweet syrup called as sapa or sugar of lead or sugar of Saturn, which contributed to lead poisoning among the Roman nobility. Hermann Kolbe synthesized acetic acid first time from inorganic compounds in 1847. The reaction sequence consisted of chlorination of carbon disulfide to carbon tetrachloride, followed by pyrolysis to tetra chloro ethylene and aqueous chlorination to trichloro acetic acid, and finished with electrolytic reduction to acetic acid. NPTEL 1 Module:2 Lecture:5 Acetic acid Dr. N. K. Patel In the first decade of twentieth century most glacial acetic acid was obtained from the "pyro ligneous liquor" from distillation of wood. The acetic acid was isolated by treatment with milk of lime, and the resulting calcium acetate was then acidified with sulfuric acid to recover acetic acid. Henry Dreyfus developed a methanol carbonylation pilot plant in 1925. However, non-existence of corrosion resistance material at high pressure (200atm) discouraged commercialization of the route. BASF, established the first commercial methanol carbonylation process, using a cobalt catalyst in 1963. Later on by Monsanto, developed a rhodium-based catalyst (cis−[Rh(CO)2I2]−) plant which is operated efficiently at lower pressure with almost no by-products in 1970. In the late 1990s, BP Chemicals commercialized the Cativa catalyst ([Ir(CO)2I2]−), which is promoted by ruthenium for greater efficiency which largely replaced the Monsanto process. In 1996 David Mehringer and his team discovered acetic acid in interstellar medium who detected it using the former Berkeley-IllinoisMaryland Association array at the Hat Creek Radio Observatory and the former Millimeter Array located at the Owens Valley Radio Observatory. It was first detected in the Sagittarius B2 North molecular cloud. Acetic acid has the distinction of being the first molecule discovered in the interstellar medium using solely radio interferometers; in all previous ISM molecular discoveries made in the millimeter and centimeter wavelength regimes, single dish radio telescopes were at least partly responsible for the detections. The formation of acetic acid furnishes an excellent example of liquidphase oxidation with molecular oxygen. Acetic acid may be obtained by the direct oxidation of ethanol, but the concentrated acid is generally obtained by oxidation methods from acetaldehyde that may have been formed by the hydration of acetylene or the oxidation of ethanol. The oxidation usually occurs in acetic acid solution in the presence of a catalyst and at atmospheric or elevated pressures. Temperatures may range, up to 1000C, depending upon conditions, but are usually lower. NPTEL 2 Module:2 Lecture:5 Acetic acid Dr. N. K. Patel MANUFACTURE 1. 2. 3. 4. 5. Acetic acid can be manufactured by following methods Methanol carbonylation Acetaldehyde oxidation Ethylene oxidation Oxidative fermentation Anaerobic fermentation 1. Methanol carbonylation Raw material Basis: 1000kg acetic acid by methanol carbonylation (95% yield) Methanol 510kg Carbon monoxide 445kg Reaction Manufacture process Rhodium catalyzed carbonylation of methanol is carried out in presence of iodine as activator. Methanol and carbon monoxide were charged into carbonylation reactor at partial pressure between 10 - 15bar while the temperature is maintained at 1750C. The exhaust gas from the reactor is coming out from the top and introduced into gas scrubber where gases coming out from purification section are also scrubbed using methanol and then recycle to reactor. Reactor used in carbonylation of methanol is bubble column reactor. This reactor provides excellent mass and heat transfer. In this reactor gas is sparged from the bottom of the reactor. Design of the sparger controls the bubble size distribution in the column. While remaining mixture from the reactor is heated in flash tank where vapour is transferred to crude column for distillation while liquid coming out from bottom is recycled to reactor. In crude acetic acid column, light end are vaporized and send to light ends column where they are removed. Liquid coming out from bottom is again heated in flash tank and acetic acid - NPTEL 3 Module:2 Lecture:5 Acetic acid Dr. N. K. Patel water mixture is taken out from side cut and charged in to dehydration column where methanol is introduced. Gas scrubber Purge Flash tank CO Steam Light end column CO Methanol Crude acetic acid column Carbonylation reactor Purge Waste acid column Methanol Acetic acid Acetic acid column Dehydration column Methanol Waste acid Figure: Manufacture of acetic acid by methanol carbonylation Block diagram of manufacturing process Diagram with process equipment Animation After dehydration, liquid mixture from bottom of column is charged into acetic acid column where acetic acid is obtained as product. Waste acid are removed using stripping operation. 2. Acetaldehyde oxidation Raw material Basis: 1000kg acetic acid by acetaldehyde oxidation (87% yield) NPTEL 4 Module:2 Lecture:5 Acetic acid Dr. N. K. Patel Acetaldehyde Oxygen 845kg 615kg Reaction Manufacture process Nitrogen Cooled water Acetaldehyde still Waste Cold Water Water Scrubber Heat exchanger Steam Air Oxidizing kettle Refined acetaldehyde Heat exchanger Manganese acetate Water Acetaldehyde from acetylene hydration Acetic acid still Heat exchanger Steam Crude acetic acid Refined acetic acid Figure: Manufacture of acetic acid from acetaldehyde Block diagram of manufacturing process Diagram with process equipment Animation Acetaldehyde from acetylene hydration was preheated in heat exchanger and purified in acetaldehyde still by distillation. Purified acetaldehyde was stored in refined aldehyde storage tank. Then refined NPTEL 5 Module:2 Lecture:5 Acetic acid Dr. N. K. Patel aldehyde was charged in to oxidation vessel from top in counter current direction of air as a source of oxygen from bottom. The reaction vessel consists principally of aluminum-lines steel vessel fitted with air distributor. In operation, previously cooled acetaldehyde at 0-50C was introduced, and then manganese acetate is added either in the form of saturated acetic acid solution or as a powder ground to pass 200 mesh sieve. At the same time air was introduced through the distributor head and temperature was raised by steam by passing through the aluminum coils. The heat of reaction must be removed by cooling water, which is substituted for the initial steam. Temperature plays an important role for the oxidation reaction. It should be maintained 270C for 1st hrs. Then increase of 1 to 20C for 2hrs and gradually increased up to 600C after 4hrs. The most satisfactory operating temperature is about 600C. The reaction takes 12-14hrs for completion. The pressure was kept below 5 kg/cm2. The nitrogen being vented through a series of condensers attached to the dome. Condensed aldehyde was returned to the kettle. The nitrogen was passed through water scrubbers to remove the last traces of the aldehyde, which is later recovered. Acetic acid, exceeding 96% strength was obtained. Distillation is carried out for final concentration and purification of acid. The yield varied from 88-95% of the theoretical. NPTEL 6
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