Organic compounds -- part of the class 532-570 series – Organic compounds – Aluminum containing
Reexamination Certificate
2003-05-27
2004-05-11
Nazario-Gonzalez, Porfirio (Department: 1621)
Organic compounds -- part of the class 532-570 series
Organic compounds
Aluminum containing
C556S190000, C205S237000
Reexamination Certificate
active
06734317
ABSTRACT:
The present invention relates to a process for preparing alkali metal tetraalkylaluminates, in particular potassium tetraethylaluminate, and also to the use of such an aluminate complex in aluminum deposition by electroplating-electrolysis.
Alkali metal tetraalkylaluminates are used in the aluminizing of base metals. The aluminum layer deposited electrolytically on the base metal protects this against corrosion, and in addition the aluminum layer has in part decorative character.
Aluminizing is possible in principle by various methods. For example, aluminum can be deposited on a substrate electrolytically by fused-salt electrolysis or from solutions.
In the case of deposition from a solution, it is necessary to take into account the fact that aluminum itself is very base and is only protected against further oxidation by an oxide layer adhering at the surface. Therefore, anhydrous media in organic solvents must be employed. Aluminum compounds which are suitable for aluminizing that are used are trialkylaluminum compounds, but in particular the complex tetraalkylaluminates which, as salts in the organic solvents, in addition make possible the current density which is required for rapid and uniform electrodeposition.
The use of potassium tetraethylaluminate has proved to be particularly advantageous, since, in addition to good commercial availability, the above-described conditions of the necessary current densities for rapid and uniform electrodeposition can also be achieved.
In the literature, known processes for preparing sodium tetraethylaluminate start from triethylaluminum which is reacted with liquid sodium, sodium tert-butoxide or other sodium alkoxides. In addition, sodium tetraethylaluminate can be produced from ethene and a triethylaluminum-sodium hydride complex (Houben-Weyl, Methoden der organischen Chemie [Methods in organic chemistry], Tubingen 1970, Metallorganische Verbindungen Vol. XIII/4, pages 123-135; Liebigs Ann. Chem. 705 (1967) p. 43).
The methods known in the literature for preparing potassium tetraethylaluminate include the reaction of triethylaluminum with potassium tert-butoxide and a reaction of sodium tetraethylaluminum with potassium chloride or with potassium amalgam (Houben-Weyl, Methoden der organischen Chemie [Methods in organic chemistry], Tubingen 1970, Metallorganische Verbindungen Vol. XIII/4, pages 123-135; Liebigs Ann. Chem. 705 (1967) s. 43) in a similar manner to the reactions for sodium tetraethylaluminate.
The preparation processes of the prior art have some disadvantages.
The direct preparation of the potassium salt has the problem that the product is difficult to isolate and has a strong discoloration.
All preparation routes via amalgams (Na/Hg or K/Hg) are of concern for toxicological reasons alone.
The preparation pathways for NaAlEt
4
via elemental liquid sodium also have processing problems due to the use of pyrophoric liquid sodium.
The addition of ethene to NaH·TEA is very problematic with respect to reaction conditions, since the “run away” of the reaction can be prevented only in a narrow temperature window. Furthermore, the preparation is more complex in processing terms owing to the handling of gaseous reactants and the removal of residual NaH·TEA.
The preparation of KAlEt
4
starting from KOtBu+TEA likewise has problems: the reaction is performed at high temperatures and KAlET
4
is not produced as solid (owing to its high solubility in hydrocarbons and due to formation of complexes), and therefore complex phase separation is necessary. High-boiling paraffins are used as process solvent. The purity has a tendency to be poor.
Thus U.S. Pat. No. 3,285,947 also indicates the problems of synthesizing pure KAlEt
4
, but proposes as a solution the route via potassium amalgams.
WO 00/32847 (=EP 1 141 447) also describes the use of sodium tetraethylaluminate and/or potassium tetraethylaluminate as constituents of an electrolytic system for depositing aluminum or magnesium onto differing substrates by electroplating. There, however, the synthesis of the sodium tetraethylaluminate is not mentioned and the synthesis of potassium tetraethylaluminate at high temperature is described.
Complexes of sodium fluoride and triethylaluminum in toluene or xylene are usually used as electrolyte. However, because of their disadvantages of nonuniform coating, in particular in the case of edged, angular substrates, these have been overtaken in the interim.
An object of the present invention is a simple and efficient process for preparing alkali metal tetraalkylaluminates, in particular potassium tetraalkylaluminates.
This object is achieved by a process as claimed in claim
1
.
The invention relates to a process for preparing alkali metal tetraalkylaluminate, which comprises adding trialkylaluminum to a solution of alkali metal ethoxide in hydrocarbon, alkali metal tetraalkylaluminate being formed.
An advantage of the inventive process is that by adding trialkylaluminum to a solution of alkali metal ethoxide in hydrocarbon the reaction can readily be controlled, which is accompanied, in particular when sodium ethoxide is chosen (in contrast to other alkoxides), by a plurality of advantages in the preparation of sodium tetraethylaluminate:
1. good commercial availability, simple preparability compared with sodium butoxide
2. production of a further commercially utilizable product diethylethoxyaluminum (DEALOX).
The invention further relates to a process for preparing alkali metal tetraalkylaluminates, which comprises reacting the alkali metal tetraalkylaluminate, which is formed in a first above-described process step, with an alkali metal halide in a further process step to form a cation-exchanged alkali metal tetraalkylaluminate.
The preferred inventive process having the additional double decomposition step is described below with the example of preparing potassium tetraethylaluminate, which is not, however, to be considered to be a restriction of the processes claimed and their process steps.
According to a preferred embodiment, sodium ethoxide is reacted with triethylaluminum to form sodium tetraethylaluminate and diethylethoxyaluminum (DEALOX). For this reaction NaOEt in hydrocarbons is charged and triethylaluminum is added. Suitable hydrocarbons are, in particular, heptane and toluene and mixtures thereof. The products are optionally isolated by decanting or filtration. DEALOX is obtained as a utilizable byproduct. This can be purified in principle by distillation or produced as a hydrocarbon solution.
In an additional step, after isolation of the sodium tetraethylaluminumate intermediate, the double decomposition with KCl can be performed in toluene to give potassium tetraethylaluminate.
Then, a formulation for the deposition of aluminum by electroplating-electrolysis can be prepared by adding toluene and triethylaluminum in varying amounts. The double decomposition step and the preparation of formulation step can also be carried out in combination.
The inventive preparation of potassium tetraethylaluminate via sodium tetraethylaluminate using a double decomposition process has a number of advantages compared with known processes:
1. simple process (no complex drying, no liquid—liquid phase separation)
2. tandem production of diethylethoxyaluminum (DEALOX)
3. good control of the reaction (in contrast to NaH·TEA+ethene) by charging NaOEt and adding triethylaluminum
4. high purity together with very good yield (high yield/avoidance of caking, in particular when toluene/heptane or heptane alone is used as process solvent)
5. ability to set any ratio between NaAlEt
4
and KAlEt
4
(5-95%) (important for preparing electrolytes)
6. use of inexpensive nontoxic starting materials such as NaOEt and KCl.
The alkali metal cations can be sodium, potassium and rubidium, with the alkali metal tretraalkylaluminate formed in the first process step preferably containing sodium and the alkali metal tetraalkylaluminate formed in the additional second step preferably containing potassium.
Halides which may be used in the
Heitmann Peter
Hüttenhofer Mario
Wanke Thomas
Crompton GmbH
Dilworth Michael P.
Nazario-Gonzalez Porfirio
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