DE1002750B - Process for the electrolytic production of sebacic acid from its alkali salts - Google Patents

Description

Process for the electrolytic production of sebacic acid from their Alkali Salts The invention relates to the production of sebacic acid by electrolysis the solution of one of its water-soluble salts in a cell, the one for cations contains permeable membrane between the anode and the cathode and in which the anode compartment the aqueous solution of the sebacic acid salt, the cathode compartment the aqueous solution an electrolyte, preferably an alkali hydroxide. The anode from The membrane separating the cathode compartment contains at least 25 percent by weight of a cation exchanging resin.

Sebacic acid is a technically important substance that is necessary for the production synthetic resins and plasticizers are widely used. She will be in technical dimensions by heating ricinoleic acid ester-containing material, e.g. B. an ester of ricinoleic acid. As the main starting material for sebacic acid, castor oil is used, which is largely made up of ricinoleic acid glycerol ester consists. Various methods for the pyrolysis of ricinoleic acid esters (cf.e.g. U.S. Patents 2,182,056, 2,217,515, 2,470,849, 2,217,516, and 2,580,931).

In these production methods, sodium and sodium are obtained first or or the potassium salt of sebacic acid, which is then mixed with an inexpensive mineral acid, z. B.

Sulfuric acid, or hydrochloric acid, is acidified to produce the free sebacic acid to set in freedom.

The present invention aims to provide an improved method for converting the alkali bacates into sebacic acid while avoiding the use a mineral acid and formation of its alkali salts, as well as the use of electrical Energy in place of chemicals for the conversion of sebacic acid salts into Sebacic acid.

The necessary to carry out the method according to the invention electrolytic cell can be seen from the schematic drawing. 1 means one in two compartments 5 and 6 through a membrane 2 permeable to cations divided container, which is described in more detail below. 5 is the anode compartment, 3 shows an anode, while 6 shows the cathode compartment and 4 shows the cathode. When the cell is in operation, the electrodes 3 and 4 are not shown with an electrical Energy source connected.

Although the following description of the procedure is for reasons Limited to the use of sodium sebacate for simplicity, one can too use the salts of potassium and lithium.

When performing the procedure, a sodium sebacate solution is added to the Anode compartment 5 and a dilute sodium hydroxide solution are introduced into the cathode compartment 6. An electric current is then passed through the cell, causing the ions in wander each of the two spaces towards the oppositely charged electrode. The sodium ions formed by the ionization of the sodium sebacate migrate in the direction of the cathode 4 and pass through the membrane 2 into the cathode compartment. In the course of the process, hydrogen is set free at the cathode, whereby Hydroxyl ions enter the solution according to known principles of electrolysis. At the same time, sebacic acid ions migrate to the anode, where they are discharged and themselves the sebacic acid precipitates. At the same time, oxygen is released at the anode. The hydroxyl ions try to migrate from the cathode compartment to the anode, however they are retained by the membrane 2, which as a result of their cation-active Property repels negative ions and retains them in the cathode compartment. Consequently the concentration of sodium hydroxide in the cathode compartment is gradually increased.

In the present process no mineral acid is required, oxygen and hydrogen are also obtained. Sodium hydroxide is also obtained, which can be used for alkali cleavage of further ricinoleic acid ester-containing material can.

The cell used in the method according to the invention can be used in in terms of size, shape, fasteners, building materials, switchgear, external design and the like. Be designed in various ways. It is essential that the cell-being under “Cell to understand the entire apparatus for performing the procedure is-two Has compartments, one of which contains the anode and the other the cathode, being the two departments through one that is permeable to the cations Membrane are separated.

The use of such a membrane is crucial for the Success of the process.

The composition of the membrane can fluctuate within certain limits, but it is essential according to the present invention that the membrane at least Contains 25 percent by weight of a cation exchange resin. The selectively permeable Membranes found to be best suited for use in this procedure are those which are exchanged by the incorporation of particles of a cation Resin into a film-forming die, e.g. B. made of polyethylene, polyvinyl chloride, natural rubber or synthetic rubber, and between 25 and 75 ° 0 of a cation interchangeable resin, either of the sulfonic acid or carboxylic acid type.

They are strong and pliable so that they can be easily attached to the cell can. Furthermore, they are and will be resistant to the action of chemicals not by the solution of sodium or potassium hydroxide with which they are during the Contact with electrolysis is destroyed. There are also others for cations selectively permeable films known e.g. B. those based on cellophane or collodion, but these do not contain any cation-exchanging resins and are unlikely to be destroyed by alkaline solutions for use in the method according to the invention not recommendable.

Cation exchange resins are widely used for removal used by ions from liquids, e.g. B. in softening water. Suitable Cation exchange resins are described in U.S. Patents 2,184,943.2 195 196.2 204 539.2 228 159, 2228 160, 2230 641, 2259 455, 2285 750, 2319 359, 2366 077,2 340 110 and 2,340 111. Some of the resins can be poured or otherwise in the form of membranes. You can also use the cations Produce exchangeable resins on a porous base, e.g. B. on a piece of tissue or on a perforated plastic plate. As mentioned above, these are the most preferred membranes permeable to cations are those that have a Cation-exchanging resin contain, preferably a sulfonated phenol-formaldehyde resin or a sulfonated copolymer of a monovinyl hydrocarbon, such as styrene, with a polyvinyl hydrocarbon such as divinylbenzene, the particles of which in a Layer of an alkali-resistant matrix are dispersed.

As the electrical current through the selectively permeable membrane means Cations are passed through in conjunction with the cation exchange resin must, it is important from the standpoint of economy that the cation-exchanging Resin a substantial portion - at least 25 and preferably 40% - of the selective permeable membrane forms.

The partition wall is usually of an order of magnitude in thickness from 0.51 to 2.54 mm, although thicker membranes have also been used successfully Has.

The electric current is direct current and it becomes a current density from about 50 to 200, preferably 90 to 180 amps per 930 cm2. Which current density is to be maintained in detail depends on the design and Size of the cell as well as the other prevailing process conditions.

The salt of sebacic acid must and usually will be water-soluble Sodium or potassium salt or a mixture of the two. Most often there is it made from disodium sebacate. In the meantime it is sometimes in the production of sebacic acid, z. B. from castor oil, desirable worth partially acidifying the pyrolysis product, to the other acids, like stearic acid, which together with the sebacic acid form, separate. In such cases, a solution of all the salts except for acidified to a pH of approximately 5.8, with monobasic acids under these conditions can be knocked down and removed. This leads to the formation of something acidic Sodium or potassium sebacate, which is, however, obtained by the process according to the invention electrolyzed in the same way as the neutral salt. The presence of others Salts, e.g. B. inorganic salts as impurities in the solution of alkali bacates, is of course not desired, but interferes with the electrolysis of the sebacate solutions not, Compliance with a special concentration of the alkali hydroxide solution in the Cathode space at the start of the procedure is not essential as it progresses more hydroxide is formed during electrolysis. However, it is recommended that the Concentration at the beginning is at least 0.1N and preferably normal. Any suitable Electrolyte, e.g. B. sodium chloride, if desired, can be used in the cathode compartment but such a substance naturally contaminates the alkali hydroxide that is formed forms during electrolysis.

Serves to further illustrate the method according to the invention the following example: Example It was an electrolysis cell in the drawing the type shown. She was in an anode room that had a platinum electrode contained, and in a cathode compartment, which also contained a platinum electrode, subdivided by means of a membrane that is selectively permeable to cations. The membrane was by dispersing a commercially available cation exchange resin in a film of polyethylene in a rubber mixer. That Cation exchange resin comprising 60 percent by weight of the selectively permeable membrane was a sulfonated copolymer of styrene and divinylbenzene (nAmberlite I. R. 120 "), which is manufactured according to the method of US Pat. No. 2,366,007 became.

150 parts of a 3.77 "/ in aqueous solution were put into the anode compartment Introduced by monosodium sebacate.

The solution contained a small amount of sodium sulfate as an impurity. 150 parts of a 1.07 N solution of sodium hydroxide were placed in the cathode compartment.

A direct current was passed through the cell for 23/4 hours at a current density of approximately 90 amps per 930 cm2 passed through. As the conductivity of the solutions while the electrolysis changes, it was necessary to increase the voltage to an amount of between 5 and 10 volts to maintain the mentioned current density.

A voluminous white precipitate of sebacic acid formed during the electrolysis in the anode compartment, while the sodium hydroxide concentration in the cathode compartment increased. At the end of the process, the sebacic acid was removed and dried. Was received a yield of 5.1 parts, which means a more than 90 "/,) igue yield. Im In the cathode compartment, the concentration of the sodium hydroxide solution was 1.72 of normal increased.

A total of 0.072 kilowatt hours of electricity was used. Here, sebacic acid was used in an amount of 453 g per 6 kilowatt hours of electricity set free, and 317 g of sodium hydroxide were obtained simultaneously. Even Oxygen and hydrogen were at the anode and cathode respectively during operation set in freedom.

The method according to the invention is much more advantageous than that previous operation with the usual known porous membranes, such as the one below comparative experiment described proves.

A cation exchange membrane (A) was compared with a commercially available one Asbestos membrane (B).

The same cell was used in both cases, in which only the above-mentioned cell was used Membranes were used alternately. The cell was opposite that in the registration example described cell, apart from the membrane, of an improved construction, so that the test results given below are still somewhat better than the numbers given in the application example. In each case the anolyte consisted of a 4.5% solution of monosodium sebacate, the catholyte from a 0.1 N solution of NaOH.

In both cases the current density was 90 amperes per unit area (Square feet) of the membrane.

The cell was operated with each of the two membranes for so long until the anolyte reached the pE value of at least 2.

The results of the comparative experiment are shown below Table compiled: A B Current density (Amp./3) 90 90 Operating time (minutes) .... 58 124 pg anolyte after this time 1.5 1.7 weight sebacic acid 6.5 6.2 yield ................. 95 ° / 0 90 ° / O total kilowatt hours .. 0.0472 0.0872 A B kilowatt hours per pound Sebacic acid 3.3 6.4 Ampere efficiency ..... 77.3 ° / 0 30.9 ° / 0 This results in that when using the asbestos membranes, although they are more than twice as long as the exchange membranes were kept in operation, not even the absolute amount of sebacic acid, which results in the use of the exchange membrane. The yield and the degree of efficiency are therefore much more favorable with this. the Production costs of the sebacic acid are only approximately in the process of the application half the cost of working with the usual asbestos membrane.

Claims (1)

PATENT CLAIM: Process for the production of sebacic acid by Direct current electrolysis of their aqueous alkali salt solutions, whereby the anolyte is made of such a salt solution, the catholyte from an aqueous solution of the corresponding Alkali hydroxide consists, characterized in that as a diaphragm between the electrode spaces a cation-permeable membrane used, which to at least 25 percent by weight of a cation exchange resin. References Considered: U.S. Patents No. 2 033 732.2 592 686.