EP1312700A2 - Process for the production of alkali metal alcoholates - Google Patents

Abstract

In electrochemical production of alkali alcoholate (I) from a saline aqueous anolyte and an alcoholic catholyte, the cathode and anode compartments are separated by a solid electrolyte which is stable towards the anolyte and catholyte and conducts only ions. <??>An Independent claim is also included for electrolysis cell, comprising an anode compartment with an aqueous solution of alkali metal salt(s) as anolyte, a cathode compartment and a solid electrolyte as membrane separating the anode and cathode compartments, in which the solid electrolyte has no other ion-conducting layer.

Description

The present invention relates to a method for electrochemical production of alkali alcoholates and an electrolytic cell to be used for this purpose. In particular, the inventions are directed to such Production method in which aqueous salt solutions on the anode side can be used.

Alkaline alcoholates (Na / KOMe / OEt etc.) are among the Standard products of the chemical industry, whereby especially those with alcohol components up to 4 Contains carbon atoms, valuable chemicals in the represent organic synthesis.

There are several methods for the synthesis of alkali alcoholates known (F.A. Dickes, Ber. Dtsch. Chem. Ges. 1930, 63, 2753). A special method of making the Alcoholates deals with the drainage of Solutions that contain the alcohol and the corresponding Have alkali hydroxide in equivalent amounts. It can the shift in equilibrium towards the desired product by distillation measures or with the help of semi-permeable membranes are made (EP0299577).

You get to the alcoholate directly when you get one Dissolves alkali metal in the corresponding alcohol. sodium and potassium react so stormily with lower ones Alcohols that use on an industrial scale too would be risky. Higher or branched chain alcohols sometimes react too slowly. A solution to this Problems suggests e.g. the DE19802013. From the Chloralkali electrolysis derived amalgam is under catalytic effect of transition metal nitrides and - carbides implemented with alcohols. This procedure hides the disadvantage that the alcohols more or less only with Mercury can be obtained contaminated. to Further processes are necessary for de-quenching (DE19704889).

DE3346131 also proposes an electrochemical Procedure in which using a Cation exchange membrane as separator material Akali metal ions from alcoholic salt solutions on the anode side are produced by the membrane in the cathode compartment migrate in which, under the evolution of hydrogen, alcohols are converted into their anions.

US5,425,856 discloses a continuous one electrochemical process for the production of Alkaline alcoholates based on alcoholic salt solutions. This method has the disadvantage that in the anode compartment process-related chlorinated alcohol compounds as By-products arise, some of which are more pathogenic Character is well known.

DE19603181 also proposes an electrochemical process for the preparation of alkali alcoholates. Here are Anode and cathode space through an ion-conducting Solid electrolytes completely separated to be a disadvantage Prevent mixing of the anolyte and catholyte solutions.

The electrochemical processes just mentioned have in common that they work entirely in alcoholic solution. The Conductivity of such systems is limited, which is why small electrode gap or the addition of a conductive salt to the solution condition is to turn sales on one to raise tolerable levels.

PCT / EP00 / 08278 describes a process for the production presented by alkali metals. Here, you put in An anode solution an aqueous solution of an alkali metal salt and separates this compartment helium-tight from e.g. a cathode compartment having a steel cathode. As Liquid electrolyte on the cathode side becomes a molten salt proposed. It is clear that with this method a Mixing of anolyte and catholyte under all circumstances must be avoided. Therefore, as a separator Solid electrolyte proposed that only the considered cations and in particular diffusion completely prevented by water into the cathode compartment. As separators resistant to aqueous systems only coated ion-conducting solid electrolytes proposed.

The object of the present invention was another electrochemical process for the production of To show alkali alcoholates, which has the disadvantages of Helps overcome the state of the art. In particular, should this process from an economic and ecological point of view technical scale to be very well applicable. That is, that Method according to the invention while avoiding the emission pathogenic substances a cost-efficient representation of the should ensure desired products.

However, these and others not mentioned here result from the State of the art in an obvious manner Tasks are carried out using a procedure with the characteristics of Claim 1 solved. Claims 2 to 10 protect preferred Refinements of the method according to the invention. Expectations 11 to 17 are on an electrolysis cell according to the invention directed. Claim 18 is directed to a preferred Use of the electrolytic cell.

The fact that in a process for electrochemical Production of alkali alcoholates from one saline aqueous anolyte and an alcoholic Katolyt, the cathode and anode compartment by one only ion-conductive anolyte- and catolyte-stable Solid electrolyte are separated, one gets extremely surprising but no less advantageous kind and way to an industrially applicable cost-effective manufacturing processes. With the The method according to the invention has succeeded in being favorable related aqueous salt solutions and simple alcohols using water sensitive electricity Produce alkali alcoholates without the risk of Contamination of the products with mercury. On the other hand, due to the electric current can be good conductive aqueous anolyte solution the voltage used lower relative to the prior art methods be kept, which is a less expensive manufacture of the Alkaline alcoholates allowed. To further increase the Conductivity of the cell can also affect the catholyte Conductive salt, e.g. the alkali alcoholate to be produced, in Orders of magnitude of <5% by weight, preferably <4% by weight, more preferably <3% by weight and very particularly preferably <2 % By weight are added.

In principle, all ion-conducting solid electrolytes that are possible for the person skilled in the art for the stated purpose can be used, provided they meet the above-mentioned requirements. Suitable solid electrolytes should also have a conductivity which is as selective as possible for the specific alkali ion and a specific resistance which is as low as possible. Solid electrolytes of this type are mentioned inter alia in GB 1155927, the disclosure of which in this regard is also included here. A solid electrolyte of the β-alumina type is preferably used. The solid electrolyte has the approximate composition Alk ₂ O ₁₁ Al ₂ O ₃ , where Alk is preferably sodium, potassium or lithium, depending on which alkali metal alcoholate is to be produced. The solid electrolyte can optionally also be equipped with the ion-conducting coatings described in PCT / EP00 / 08278. In this regard, the disclosure of PCT / EP00 / 08278 is considered to be included here.

A variant according to the invention is preferred in which the Solid electrolyte on one or both sides with one or several ion-permeable electrically conductive layers is coated. Preferably, the ion-permeable electrically conductive layer on the solid electrolyte evaporated or as an immersion layer on its surface fired. Manufacturing process for such coated Solid electrolytes can in principle be found in the literature (Edelmetall-Taschenbuch, ed. Degussa Ag, 2nd ed. Hüthig-Verlag Heidelberg; Thick film technology: a user's sorry. London, Andy. Cermalloy Div., Heraeus Inc., West Conshohocken, PA, USA. Editor (s): Kordsmeier, N.H., Jr .; Harper, Charles A .; Lee, Stuart M .; Electron. Mater. Processes, Int. SAMPE Electron. Conf., 1st (1987), Materials science of thick film technology .; Vest, R. W. Purdue Univ., West Lafayette, IN, USA .; At the. Ceram. Soc. Bull. (1986), 65 (4), 631-6.). By burning the Primer layer at sometimes> 1200 ° C can be the stability of the solid electrolyte compared to the anolyte or Increase catholyte solutions further. Again is preferred the embodiment in which the cathode and anode side with an electrically conductive porous Layer coated surface of the solid electrolyte with the downstream or supplying means is in contact. This The embodiment described has the advantage that only the solid electrolyte between the primary anode and cathode is, which is the penetration resistance, which is can be characterized as a voltage drop in the cell, can be significantly minimized.

The solid electrolyte can all be familiar to the person skilled in the art Shapes such as sleeves, disks or tubes. However, preference is given to the two accessible surfaces in the form of a solid electrolyte a plane-parallel plate, preferably a disc, used.

Another one to be used advantageously Process design consists in the fact that Anode and / or cathode compartment with electrical conductive powders is filled to the Potential distribution in the catholyte and anolyte improve. In addition to the electrical properties here also the catalytic effectiveness on the formation of Alcohol ions and the improvement of the oxidation reaction consider. With this measure the Electrode surface area enlarged, which Overvoltage phenomena in particular Diffusion problems are reduced as much as possible. All preferably come as electrically conductive powders those in question, on the one hand, for amalgam decomposition in alcohols (DE19802013) and on the other hand for the Anode coating in electrolysis (V. de Nora, J.-W. Kühn von Burgsdorff, Chem. Ing. Tech. 47 (1975) 125-128. Electrochemical Engineering: Science and Technology in Chemical and Other Industries; Wendt, H .; Kreysa, G. (1999), 277, pp.265ff; Electrode materials for electrosynthesis. Couper, A. Mottram; Pletcher, Derek; Walsh, Frank C., Chem. Rev. (1990), 90 (5), 837-65) become.

In particular, these are metal powders in the catholyte space of any kind, provided that under the circumstances are sufficiently stable and do not lead to contamination the alkali alcoholates when performing the process. Preferred powders to be used are nickel, tungsten, To name titanium, copper or steel powder. Especially the use of Hastelloy powders is preferred. On Another powder that can be used is graphite. This can alone or in combination with those just described Metal powders or modified based on DE19802013 be used.

In the anolyte room are graphite powder, titanium and materials used for dimensionally stable anodes find (Ullmann's Encyclopedia of Industrial Chemistry, Vol.A6, 450-454, VCH Weinheim, 1986, D.L. Caldwell in Comprehensive Treatise of Electrochemistry Vol2, Plenum 1981 ed. Bockris, J O'M, pp. 122-126, and Comninellis, C .; Vercesi, G.P.J. Appl. Electrochem. (1991), 21 (4), 335-45, Hinden, Jean Marcel; Beer, Henri Bernard. dimensionally stable coated electrode for electrolytic process, comprising a protective oxide interface on valve metal base. Eur.Pat.Appl. (1982)). Graphite is preferred used.

Alcohol is the catholyte in electrolysis used, which is to form the alkali alcoholate. As an anolyte one has larger ones with regard to the salt solutions to be used Freedoms. Such salts are preferably used Use electrolysis, which can be obtained inexpensively can. The concentration of the salt solution should be as possible be high. Saturated solutions of are therefore preferred Carbonates, chlorides, sulfates, sulfites, hydroxides etc. used. The use of. Is very particularly preferred Carbonates, sulfates and chlorides. The saline Anolyte solution should depend on the use of the solid electrolyte have such a pH at which this has maximum stability. Since it is the Solid electrolytes preferably around oxides of aluminum which is higher in the basic pH range have chemical stability, the anolyte is complete particularly preferred for pH values> 7, extremely preferred> 8 adjust.

The current characteristic and thus the sales with a to achieve such procedures is very strong temperature dependent. The higher the temperature at the Electrolysis, the higher the current flow given voltage. The temperature should therefore be off Efficiency reasons are kept as high as possible. Out from a process engineering point of view, boiling of the anolyte or catholyte solutions can be avoided. Still can one above the boiling point of the one used Solutions work if you put them under pressure. Here, however, the pressure resistance of each used solid electrolyte the amount of pressure one natural border. Preferably, the temperature of the Anolytes during electrolysis in an interval of> -10 ° C, preferably> -5 ° C, to <+ 0 ° C, preferably <-1 ° C, calculated from the boiling point of the anolyte. As well becomes the temperature of the catholyte during electrolysis especially with a continuous feed in one Interval from> -45 ° C, preferably> -20 ° C, to <-5 ° C, preferably <-10 ° C, calculated from the boiling point of the catholyte set. In the case of a batch process (no circulation of Anolyte and catholyte) the temperature of the catholyte is about 1 - 2 degrees higher than in the anolyte.

In particular, by arranging a disk as a solid electrolyte with two electrolyte spaces, which in turn have an inlet and outlet, it is possible to design the process continuously. A washer with a diameter of 70 mm is fixed between two half-shells using an appropriate sealing system. The sealing system seals both cavities (anolyte and catholyte space) airtight and thus prevents the electrolyte solutions from crossing into one another. The electrolyte spaces (approx. 25 ml) can be flowed through in a defined manner using peristaltic pumps. The volume flow is advantageously chosen for the aqueous anolyte sols in a range from 0.1 l / h to 10 l / h, preferably 1 l / h to 2 l / h. The anolyte can be heated using a thermostat in order to adjust the temperature. If the anolyte compartment is filled with powder, a separator system (filter) should be connected upstream of the outlet line.
With this procedure, the catholyte solution is also pumped through the catholyte compartment and optionally separated from entrained powder by means of a filter insert before leaving the catholyte compartment.
Due to the arrangement at the level of the screen, it is possible to heat the anolyte substantially above the boiling point of the catholyte alcohol system. In order to prevent the alcohol system from boiling, the catholyte should not be continuously heated, and cooling may be provided. Only at the beginning of the experiment should the catholyte be run in the temperature range specified above in order to quickly obtain the desired reaction rate. Advantageously, to further prevent boiling of the alcohol, its flow rate can be increased accordingly. The volume flow can be between 1 and 10 l / h, preferably in the range 2 to 5 l / h.
The continuous cycle procedure causes the resulting gaseous products to be removed from the electrolyte compartments. In order to prevent pressure build-up in the overall arrangement, the intermediate containers which were used as a pump template and for thermostatting can be equipped with nitrogen-blanketed reflux coolers which are open at the top.

The anode material to be used in the process in question is familiar to the person skilled in the art. In principle, the materials listed in PCT / EP00 / 08278 are to be used for this purpose. Preferably, a material as mentioned above for filling the anode space is also used as the anode material.
The same must be stated for the cathode material.

In a next embodiment, the Invention with an electrolytic cell, comprising a Anode compartment containing at least one aqueous solution an alkali metal salt as anolyte Cathode compartment and a solid electrolyte as Membrane through which the anode compartment and the Cathode compartment are separated from each other, wherein the solid electrolyte is no further ion-conducting layer having. In contrast to the PCT / EP00 / 08278 you have surprisingly found that the ion-conducting Layers of coated solid electrolytes there listed genus also compared to those used Solutions have sufficient stability to technical scale can be used.

In principle, those mentioned above come as solid electrolytes mentioned materials in the also listed there Versions (ion-permeable, electrically conductive Coating, contacting with current-carrying agents, plane-parallel plate, etc.).

Preferred electrolysis cells are otherwise based the preferred ones set out above for the process Embodiments.

Another embodiment of the invention relates on the use of the invention Electrolytic cell for the production of alkali alcoholates. It is also a use analogous to PCT / EP00 / 08278 conceivable.

In the context of this invention, the expression permeable to ions understood that due to Porosity and not due to defects (as with the Ion conduction) in the material ions through this material can diffuse.

Examples: Determination of water stability

An arrangement of the solid electrolyte is designed so that an outsourcing of a sleeve (tube open at the top) in aqueous solutions is possible. This is the interior tightly sealed with a seal and glass top. The Glass top is with an outlet valve for pressure equalization and equipped for sampling. The sleeve is in one thermostable vessel fixed that in turn with a saturated soda solution is filled. The sleeve itself will filled with 30% sodium methylate solution. The Aging test is carried out at a temperature of 60 ° C carried out. The resistance of the solid electrolyte will by weekly determination of the water content in the Alcoholate solution checked. After 3 months the trial can be started be stopped without being in the alcoholate solution increased water content can be demonstrated.

In a second experiment, a washer (D 70mm) fixed between two half-shells, which are also on the one hand with sat. Soda and on the other hand 30% alcoholate solution are filled. The half-shells in turn become tight finally attached to the pane and the surrounding area. The Construction is done in a water bath at 60 ° C thermostated. After 3 months there can be no water in the Alcoholate solution can be found.

Claims (18)

Process for the electrochemical production of Alkaline alcoholates starting from a saline aqueous anolyte and an alcoholic catholyte, wherein Cathode and anode compartment by one only ion-conducting anolyte and catolyte stable Solid electrolyte are separated. Method according to claim 1,
characterized in that
β-alumina is used as the solid electrolyte. Method according to claim 1 and / or 2,
characterized in that
the solid electrolyte is coated on one or both sides with one or more ion-permeable electrically conductive layers. Method according to one or more of the preceding claims,
characterized in that
the ion-permeable electrically conductive layer is evaporated onto the solid electrolyte or burned onto its surface as an immersion layer. Method according to one or more of the preceding claims,
characterized in that
the surface of the solid electrolyte coated on the cathode and anode side with an electrically conductive porous layer is in contact with the downstream or supplying means. Method according to one or more of the preceding claims,
characterized in that
the solid electrolyte is used in the form of a plane-parallel plate. Method according to one or more of the preceding claims,
characterized in that
the anode and / or cathode compartments are filled with electrically conductive powders. Method according to one or more of the preceding claims,
characterized in that
the temperature of the anolyte in the electrolysis in an interval of> -10 ° C to <+ 0 ° C and the temperature of the catholyte in the electrolysis in an interval of> -45 ° C to <-5 ° C calculated from the boiling point of the anolyte or catholyte. Method according to one or more of the preceding claims,
characterized in that
the process is carried out continuously. Method according to one or more of the preceding claims,
characterized in that
the anolyte has a pH of> 7. Electrolysis cell, comprising an anode compartment which has an aqueous solution of at least one alkali metal salt as anolyte, a cathode compartment and a solid electrolyte as membrane, by means of which the anode compartment and the cathode compartment are separated from one another,
characterized in that the solid electrolyte has no further ion-conducting layer. Electrolytic cell according to claim 11,
characterized in that
a β-alumina is used as the solid electrolyte. Electrolysis cell according to claim 11 and / or 12,
characterized in that
the solid electrolyte is coated on one or both sides with one or more ion-permeable electrically conductive layers. Electrolysis cell according to one or more of claims 11 to 13,
characterized in that
the ion-permeable electrically conductive layer is evaporated onto the solid electrolyte or burned onto its surface as an immersion layer. Electrolysis cell according to one or more of claims 11 to 14,
characterized in that
the cathode and / or anode-side surface of the solid electrolyte coated with an electrically conductive porous layer is in contact with the downstream or supplying means. Electrolysis cell according to one or more of claims 11 to 15,
characterized in that
the solid electrolyte is used in the form of a plane-parallel plate. Electrolysis cell according to one or more of claims 11 to 16,
characterized in that
the anolyte has a pH of> 7. Use of an electrolytic cell according to claim 11 for the production of alkali alcoholates.