Organic compounds -- part of the class 532-570 series – Organic compounds – Heterocyclic carbon compounds containing a hetero ring...
Reexamination Certificate
1999-08-31
2001-05-08
Kight, John (Department: 1625)
Organic compounds -- part of the class 532-570 series
Organic compounds
Heterocyclic carbon compounds containing a hetero ring...
Reexamination Certificate
active
06229018
ABSTRACT:
INTRODUCTION AND BACKGROUND
The present invention relates to a new and improved process for the preparation of nicotinic acid by the direct oxidation of &bgr;-picoline in the gas phase, wherein water and &bgr;-picoline are fed separately to the catalyst bed and the catalyst is based on a titanium dioxide support which has been prepared by the sulfate method and has a high specific surface area and a vanadium oxide content of from 5 to 50%.
Nicotinic acid is widely used in the fields of medicine and agriculture, both as a vitamin and as an intermediate for pharmaceuticals and plant growth regulators.
Various processes are known for the synthesis of nicotinic acid from &bgr;-picoline. One of those processes is liquid phase direct oxidation using HNO
3
and H
2
SO
4
(U.S. Pat. No. 2,586,555, 1952) at temperatures of from 75 to 300° C. and with yields of from 66 to 77%. Disadvantages of those processes are the high salt production that results, as well as the production of large streams of waste water. A microbiological process for oxidizing &bgr;-picoline to nicotinic acid (EP 442430, 1995) achieves a yield of 50% after a reaction time of 16 hours, the unsatisfactory space-time yield and the costly separation of the biomass from the nicotinic acid making industrial application appear disadvantageous.
In the gas phase, the ammoxidation of &bgr;-picoline to 3-cyanopyridine with subsequent hydrolysis to nicotinic acid is known (USSR Inventor's Certificate No. 235764, 1969). A disadvantage of that process is that two process steps are required, and the nicotinic acid must additionally be separated from the product mixture by means of crystallization. A total nicotinic acid yield of from 86 to 88% is mentioned. Likewise in the gas phase, there are several investigations into the direct oxidation of &bgr;-picoline using vanadium oxide catalysts. The best results mentioned are nicotinic acid yields of from 82 to 86% with the addition of air and water and at temperatures of from 250 to 290° C. (EP 747 359, WO 95/20577, 1995). The advantages of the latter process variant are that auxiliary substances and solvents are not required, with the exception of the non-critical substances water and air for the addition of oxygen. However, the yields of nicotinic acid are still markedly less than 90%. Accordingly, that process is not sufficiently economical.
An object of the present invention was, therefore, further to improve the direct oxidation of &bgr;-picoline to nicotinic acid and to achieve yields of ≧90%, in order markedly to improve the economics of the process.
SUMMARY OF THE INVENTION
The above and other objects of the present invention can be achieved by a improved process for the preparation of nicotinic acid by the direct oxidation of &bgr;-picoline wherein the &bgr;-picoline is supplied to the reactor separately from the water and wherein the &bgr;-picoline is only brought together with the water at the beginning of the catalyst bed. It is a feature of the present invention to use a catalyst that contains vanadium oxide and whose support consists of a titanium dioxide prepared by the sulfate method and having a high surface area (>100 m
2
/g), the vanadium oxide content being from 5 to 50 wt.%. Air is used as the source of oxygen, but it is also possible to use pure oxygen or a varying mixture of oxygen and nitrogen. The air is fed to the catalyst either together with the &bgr;-picoline, with the water, or separately. It is especially preferred to add CO
2
to the starting material feed, as a result of which the selectivity of the reaction can be increased further.
The yields are especially high (up to 95%) when the specific surface area of the titanium dioxide support is greater than 100 m
2
/g, especially greater than 250 m
2
/g, when the catalyst has a sulfate content greater than 0.1%, and when the vanadium oxide content is from 5 to 50%, especially from 10 to 30%. The titanium dioxide is advantageously present mainly in the anatase form.
DETAILED DESCRIPTION OF INVENTION
In the industrial preparation of titanium dioxides, two processes are distinguished, the chloride process and the sulfate process (Ullmann's Encyklopädie der technischen Chemie, 4th edition, VCH Weinheim, Volume 18, p. 569). The chloride process consists of the steps of chlorination, cooling, TiCl
4
purification, TiCl
4
combustion and TiO
2
separation. The sulfate process consists of dissolving the titanium raw material in concentrated sulfuric acid and subsequently precipitating the titanium dioxide. In detail, that process consists of the steps of decomposition, dissolution and reduction, clarification, crystallization and hydrolysis. Both processes are followed by recovery processes in order to obtain a product that is as pure as possible. A characteristic feature of the sulfate process is above all the slight residual sulfate content in the titanium dioxide, which can be reduced but not completely avoided by washing. Varying chemical properties are also associated therewith (G. A. Zenkovets, A. M. Volodin, A. F. Bedilo, E. F. Burgina, E. M. Al'kaeva, Kinetics and Catalysis, Vol. 38 (1997) p. 669).
The direct oxidation according to the present invention of &bgr;-picoline to nicotinic acid is carried out at a reaction temperature of from 150 to 450° C., preferably from 200 to 325° C. and especially from 240 to 290° C., in a fixed bed reactor; alternatively, procedures in a fluidized bed, in a moving bed and, in the liquid phase, in a fixed bed, and a multiphase procedure in a trickle bed or autoclave, are also possible.
In order to achieve good results, the molar water/&bgr;-picoline ratio is to be from 15 to 100, especially from 25 to 75, and the molar oxygen/&bgr;-picoline ratio is to be from 5 to 40, especially from 10 to 35, and the catalyst load is to be at a WHSV (weight hourly space velocity=[h
−1
]) of from 0.02 to 5 h
−1
, especially from 0.04 to 1 h
−1
and more especially from 0.05 to 0.5 h
−1
.
On account of the high yields and the ready separability of the nicotinic acid from the remaining product mixture (sublimation temperature of the nicotinic acid=235° C.), the synthesized product can be separated off at from 100 to 230° C. with a high degree of purity, and the water, the gas portions (predominantly oxygen and nitrogen), the pyridine-3-carbaldehyde intermediate and unreacted &bgr;-picoline can be recycled in gaseous form and brought together with fresh &bgr;-picoline and oxygen at the beginning of the catalyst bed. The CO
2
formed as the principal by-product by total oxidation can also be fed back, since it has been possible to establish that the addition of an additional feed gas stream or in the regas stream, which contains, for example, N
2
, Ar, CO, CH
4
, N
2
O and, especially, CO
2
, can markedly increase the yield of the reaction, which falls at higher loads.
The support materials used are various commercially obtainable titanium dioxides, which have been prepared both by the chloride method and by the sulfate method. Titanium dioxides prepared by other precipitation processes can also be used. They differ in their specific surface area, which was determined by N
2
sorption and BET evaluation, as well as in their sulfate content.
The support materials were loaded directly with vanadium oxide by the following method:
A water-soluble vanadium compound is chosen as the vanadium precursor; there are generally used ammonium meta-vanadate, vanadium acetylacetonate or vanadium oxalate. According to the desired V
2
O
5
load, the amount of vanadium precursor required therefor is converted into an aqueous solution. The titanium dioxide support material is added to that aqueous solution and the mixture is stirred. After an evaporation step, in which the water is separated off, there is obtained, with adequate intermixing, a solid consisting of the titanium dioxide and the vanadium precursor adsorbed thereon. The powdered product can then be conditioned by tempering in the usual way, as a result of which the desired V
2
O
Bock Wolfgang
Heinz Dieter
Holderich Wolfgang
Huthmacher Klaus
Krill Steffen
Degussa - Aktiengesellschaft
Kight John
Robinson Binta
Smith , Gambrell & Russell, LLP
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