Method of producing aldehydes and carboxylic acids by...

Organic compounds -- part of the class 532-570 series – Organic compounds – Carboxylic acids and salts thereof

Reexamination Certificate

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C562S534000, C568S471000

Reexamination Certificate

active

06476260

ABSTRACT:

BACKGROUND OF THE INVENTION
1. Field of the Invention
The object of this invention is a method of oxidation of alcohols in the presence of a supported catalyst containing one or more noble metals and one element of group V of the periodic system as a cocatalyst.
2. Description of the Prior Art
It is known that primary alcohols can be oxidized by oxygen as an oxidizing agent according to the following reaction scheme on copper/copper oxide catalysts:
RCH
2
OH+½O
2
→RCHO+H
2
O
and this method is used extensively in the industry. Numerous other catalysts/catalyst systems are also known. Silver and Iron-molybdenum mixed oxides which have gained industrial importance as catalysts should also be mentioned here.
Use of ruthenium supported on Al
2
O
3
for oxidation of primary alcohols is known from U.S. Pat. No. 4,996,007. However. this requires the simultaneous use of oxygen activators such as naphthaquinones or anthraquinones in the presence of solvents such as dichloromethane.
In U.S. Pat. No. 5,274,187, supported catalysts containing platinum, palladium, rhodium, ruthenium, gold, silver and/or copper are used for oxidation of polyhydroxy alcohols. These catalysts may be used in the presence of cocatalysts such as tin, lead, antimony, bismuth, selenium and tellurium. Known supports include carbon, silicates, aluminum oxide, aluminuln silicates, zeolites, molecular sieves and asbestos. The only compounds used as educts are those having at least two hydroxyl groups, at least one of which is a primary hydroxyl group and one is a secondary hydroxyl group.
Oxidation of primary alcohols (without another secondary hydroxyl group) by palladium or platinum catalysts supported on aluminum oxide or aluminum silicates in the presence of atmospheric oxygen without oxygen activators is either not known in the technical world or such catalyst systems are described as inactive (Fat Sci. Tech. 15 (94) 1992).
Furthermore, methods are known in the literature describing the oxidation of primary alcohols in the presence of solvents.
In EP-A1-0112 261 the oxidation of primary alcohols with oxygen using supported binary catalysts containing one of the noble metals of group VIII and bismuth, cadmium, mercury, indium, tellurium, tin, silver and their derivatives in the presence of polar or apolar organic solvents is disclosed. As a supporting agent in particular, carbon is named.
T. Mallar et al. (“Selective Oxidation of Cinnamyl Alcohol to Cinemalaldehyde with Air over Bi—Pt/Alumina Catalysts,” in
J. Cat.
153, pp. 131-143 (1995)) describes the oxidation of a primary unsaturated alcohol to the aldehyde over Bi-Pt/alumina catalysts exemplified by the oxidation of cinnamyl alcohol to cinemalaldehyde. The reaction is always carried out in the presence of water used as a solvent.
The object of JP 62-265243-A is the oxidation of a diol preferably in the presence of water as a solvent containing secondary hydroxyl groups only.
Furthermore, methods are known in the literature describing the oxidation of primary alcohols in the presence of solvents.
In EP-A1-0112 261 the oxidation of primary alcohols with oxygen using supported binary catalysts containing one of the noble metals of group VIII and bismuth, cadmium, mercury, indium, tellurium, tin, silver and their derivatives in the presence of polar or apolar organic solvents is disclosed. As supporting agent in particular carbon is named.
T. Mallar et al. (<< Selective Oxidation of cinnamyl alcohol to cincmalaldehyde with air over Bi—Pt/ Aluwina catalysts” in J. Cat. 153, S. 131-143 (1995)) describes the oxidation of a primary unsaturated alcohol to the aldehyde over Bi—Pt/Alumina catalysts exemplified by the oxidation of cinnamyl alcohol to cinemalaldehyd. The reaction is always carried out in the presence of water used as solvent.
The Object of TP 62-265243-A is the oxidation of a diol preferably in the presence of water as solvent containing secondary hydroxyl-groups only.
The object of the present invention is to make available a highly specific catalyst system which permits oxidation of primary alcohols, preferably long-chain primary alcohols, which need not contain any other activating groups, by atmospheric oxygen in liquid phase at low temperatures and pressures, while at the same time overcoming the disadvantages known from the state of the art such as the use of high temperatures, pressures. oxygen activators, alkali, acid or solvents.
This object is surprisingly achieved by a method of oxidizing primary alcohols containing 4 to 32 carbon atoms and are liquid at the reaction temperature and in which a catalyst containing
(a) palladium, platinum, cobalt, rhodium, ruthenium, iridium, rhenium and/or osmium, preferably palladium, platinum, cobalt and/or ruthenium, especially palladium and/or platinum, is brought in contact with the primary alcohols in the presence of a cocatalyst containing
(b) bismuth, antimony, arsenic and/or phosphorus, preferably bismuth and/or antimony, especially bismuth, supported on
(c) aluminum oxides and/or aluminum silicates is brought into contact with the primary alcohol at a reaction temperature of 20° C. to 130° C. in the absence of solvents and in the presence of molecular oxygen (O
2
).
The metals used according to this invention may of course also be in the form of compounds, especially in the form of their oxides. The catalysts used according to this invention are also active in the presence of water. The catalysts used according to this invention are advantageously activated before the start of oxidation without oxygen in the presence of the alcohol.
In addition, the reaction is preferably carried out continuously, and the primary alcohol is brought in contact with the catalyst repeatedly. Preferably molecular oxygen is used as the oxidizing agent, and for cost reasons it is used as a mixture in the form of atmospheric oxygen.
Preferred educts are primary alcohols with 4 to 32 carbon atoms, especially 4 to 16 carbon atoms. with the number of carbons preferably amounting to 8 to 32, especially 8 to 20, when an alcohol with a branch in position 2 is used as the primary alcohol.
The oxidation reaction is advantageously carried out in a fixed-bed reactor. The space velocity and residence time depend greatly on the reactor design, but a space velocity of 0.5 to 10 h
−1
and a residence time of one to ten minutes are generally set.
According to another embodiment of this method, the primary alcohol is oxidized to the aldehyde state in a first reaction, preferably keeping the conversion of the primary alcohol to the aldehyde at less than 40% for each contact (pass) and also preferably eliminating/removing the aldehyde by distillation.
Azeotropic distillation is preferably performed downstream from the oxidation to the aldehydes according to the present invention. In addition to the water formed in the reaction, preferably more water is added to the mixture for azeotropic distillation. At the same time, the excess water also prevents unwanted degradation reactions and side reactions (cleavage of water, formation of acetal and esterification are equilibrium reactions). In addition, the mixture is preferably acidified during azeotropic distillation or distillation is performed in the presence of acid ion exchangers.
Many aldehydes form an azeotrope with water. For example, hexanal and water form an azeotrope that boils at 91° C. Hexanol and hexanoic acid likewise form azeotropes with water, which boil at 97.8° C. and 99.9° C., respectively. Despite the fact that the boiling points are close together, the distillation process is surprisingly free of problems. Pure fractions of alcohol and aldehyde can be collected.
By adding water, the acetal formed during distillation can completely be cleaved to the educts aldehyde and alcohol. Only free hexanoic acid and ester remain in the bottom product (approximately 70%/30% in the case of oxidation of hexanol). These substances can be further separated by distillation, with the ester decomposing into alcohol and acid due to the addition of acid.
FIG.
1

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