US788315A - Method of electrolytic separation. - Google Patents

Method of electrolytic separation. Download PDF

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US788315A
US788315A US23488604A US1904234886A US788315A US 788315 A US788315 A US 788315A US 23488604 A US23488604 A US 23488604A US 1904234886 A US1904234886 A US 1904234886A US 788315 A US788315 A US 788315A
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ammonia
solution
magnesium
metal
anode
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William Hoopes
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    • CCHEMISTRY; METALLURGY
    • C25ELECTROLYTIC OR ELECTROPHORETIC PROCESSES; APPARATUS THEREFOR
    • C25CPROCESSES FOR THE ELECTROLYTIC PRODUCTION, RECOVERY OR REFINING OF METALS; APPARATUS THEREFOR
    • C25C1/00Electrolytic production, recovery or refining of metals by electrolysis of solutions

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  • My invention is especially applicable to the obtaining of magnesium by electrolysis of a solution of magnesium chlorid in anhydrous ammonia; but sodium and potassium can be produced freely in the same Way, and in general I believe that the process is applicable to the electrolytic extraction of the metal of any anhydrous salt which is soluble in anhydrous ammonia, such as the cyanids, acetates, &c.
  • My invention requires the use of :a vessel in which the ammonia can be held in liquid condition.
  • I may employ the apparatus shown in Fig. l, in which 2 is a glass vessel adapted to contain the liquid ammonia. It is set in an outer vessel 3, made of or lined with Wood or other material which is a poor conductor of heat.
  • the outer vessel 3 is filled With alcohol or other liquid of very low freezing-point, and it contains a coil of pipe 4, through which a refrigerating 'Huid-such as carbonio acid, ammonia, or the likeis caused to circulate. This chills the alcohol, which in turn' chills the liquid ammonia in the vessel 2 and prevents substantial loss by evaporation.
  • the vessel 2 contains a porous cup 5, in which is an anode 6, preferably of carbon, and in the space between the Walls of the cup 5 and vessel 2 is a cathode 7, made, preferably, of iron. Both compartments of the cell are filled With liquid anhydrous ammonia. Magnesium or other metallic chlorid is dissolved in the anode-compartment, and anhydrous magnesium chlorid with or Without a little sodium chlorid is dissolved in the cathodecompartment. Both the solution of sodium chlorid in the anode-compartment and the solution of magnesium chlorid in the cathodecompartment are preferably saturated solutions, an excess of magnesium chlorid being preferably added either loosely on the bottom of the vessel or in a suspended bag.
  • magnesium Upon passing current through the cell from the anode to the cathode magnesium is deposited on the cathode and chlorin is liberated in the porous cell, combining with the ammonia in case an insoluble anode, as carbon, is used and With the material of the anode itself in case a soluble anode, as zinc, is used.
  • Fig. 1 I may employ the apparatus shown in Fig. 2, in which the vessel 2 is simply inclosed in a heat-insulating jacket l8, so as to retard the evaporation of the ammonia as much as possible, and the vessel is provided with a cover 9, having a pipe 10, by which the ammonia-vapor as it is liberated is conducted to IOO a suitable condenser.
  • a cover 9 having a pipe 10, by which the ammonia-vapor as it is liberated is conducted to IOO a suitable condenser.
  • Many other forms of apparatus suitable for the purpose may be devised by the skilled mechanic.
  • the process can also be used for the electrolytic refining of metals in like manner as-it is done with those metals which are now purifiedby electrolysis in aqueous'solution.
  • I have purified iron by immersing an iron cathode and an iron anode containing silicon and carbon in a solution of iron cyanid and potassium cyanide in ammonia, and on passing current have obtained pure iron on the cathode, the carbon and silicon not being dissolved at the anode.
  • the obtaining of pure iron is a valuable commercial application of the process, since pure iron is now very costly, but very desirable for the production of' grades of iron and steel free from phosphorus and other deleterious impurities.
  • I claimn l The method of' electrolysis, which consists in passing an electric current through a solution of a compound in anhydrous ammonia.
  • the method of separating magnesium electrolytically which consists in passing an electric current through a solution of a compound of' magnesium in anhydrous ammonia.
  • the method of' separating'metal electrolytically which consists in passing an electric current through a solution of a compound of' such metal in anhydrous ammonia, and applying a refrigerating medium to the solution to prevent or retard evaporation of the solvent.

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  • Chemical & Material Sciences (AREA)
  • Engineering & Computer Science (AREA)
  • Chemical Kinetics & Catalysis (AREA)
  • Electrochemistry (AREA)
  • Materials Engineering (AREA)
  • Metallurgy (AREA)
  • Organic Chemistry (AREA)
  • Electrolytic Production Of Metals (AREA)

Description

PATNTED APR. 25, 1905*.
W. HOOPES.
APPLICATION FI'LED NOV. 30. 1904.
METHOD OF ELEC'TROLYTIG SEPARATION.
. WITNESSES Patented Apri125, 1905.
PATENT OFFICE.
WILLIAM HOOPES, OF PITTSBURG, PENNSYLVANIA.
IVIETHOD OF ELECTROLYTIC SEPARATION.
SPECIFICATION forming part of Letters Patent No. 788,315, dated April 25, 1905.
Application filed November 30, 1904. Serial No. 234,886.
To all whom it may concern:
Be it known that I, VILLIAM HoorEs, of Pittsburg, Allegheny county, Pennsylvania, have invented a new and useful Method of Electrolytic Separation, of Which the following is a full, clear, and eXact description, reference being had to the accompanying drawings, fornhing part of this specification, in Which- Figure l is a sectional side elevation of one form of apparatus adapted to carry out my improved method of electrolytic separation. Fig'. 2 is a similar' View of a modified form of apparatus. y
Many of the metals cannot be readily separated from aqueous solutions of their salts by reason of the fact that, the heat of formation of the oxids of the metals being greater than the heat of formation of Water, the deposited metal immediately decomposes the Water and produces as the result of the operation the oxid of the metal and hydrogen. I have discovered, however, that'if the salts of these metals be dissolved in liquid anhydrous ammonia (NH3) the solution can be readily electrolyzed and the metal obtained therefrom Without trouble, since the metalsdo not decompose ammonia.
My invention is especially applicable to the obtaining of magnesium by electrolysis of a solution of magnesium chlorid in anhydrous ammonia; but sodium and potassium can be produced freely in the same Way, and in general I believe that the process is applicable to the electrolytic extraction of the metal of any anhydrous salt which is soluble in anhydrous ammonia, such as the cyanids, acetates, &c.
I will describe the invention with reference to the separation of magnesium, which is almost impossible to effect by electrolysis of an aqueous solution; but it should be understood that I do not limit my invention thereto, but intend to claim it generically.
My invention requires the use of :a vessel in which the ammonia can be held in liquid condition. For this purpose I may employ the apparatus shown in Fig. l, in which 2 is a glass vessel adapted to contain the liquid ammonia. It is set in an outer vessel 3, made of or lined with Wood or other material which is a poor conductor of heat. The outer vessel 3 is filled With alcohol or other liquid of very low freezing-point, and it contains a coil of pipe 4, through which a refrigerating 'Huid-such as carbonio acid, ammonia, or the likeis caused to circulate. This chills the alcohol, which in turn' chills the liquid ammonia in the vessel 2 and prevents substantial loss by evaporation.
The vessel 2 contains a porous cup 5, in which is an anode 6, preferably of carbon, and in the space between the Walls of the cup 5 and vessel 2 is a cathode 7, made, preferably, of iron. Both compartments of the cell are filled With liquid anhydrous ammonia. Magnesium or other metallic chlorid is dissolved in the anode-compartment, and anhydrous magnesium chlorid with or Without a little sodium chlorid is dissolved in the cathodecompartment. Both the solution of sodium chlorid in the anode-compartment and the solution of magnesium chlorid in the cathodecompartment are preferably saturated solutions, an excess of magnesium chlorid being preferably added either loosely on the bottom of the vessel or in a suspended bag. Upon passing current through the cell from the anode to the cathode magnesium is deposited on the cathode and chlorin is liberated in the porous cell, combining with the ammonia in case an insoluble anode, as carbon, is used and With the material of the anode itself in case a soluble anode, as zinc, is used. I have found a current of live volts and a current density of .l ampere per square inch of anode-surface suitable in the separation of magnesium; but my invention is not limited thereto. As the solution in the cathode-compartment is impoverished it is replenished from time to time by the addition of more magnesium chlorid.
Instead of the refrigerating-coil shown in Fig. 1 I may employ the apparatus shown in Fig. 2, in which the vessel 2 is simply inclosed in a heat-insulating jacket l8, so as to retard the evaporation of the ammonia as much as possible, and the vessel is provided with a cover 9, having a pipe 10, by which the ammonia-vapor as it is liberated is conducted to IOO a suitable condenser. Many other forms of apparatus suitable for the purpose may be devised by the skilled mechanic.
Although my process is more particularly applicable to the separation of such electropositive metals as can be deposited with diiculty or not at all from aqueous solutions, it nevertheless possesses general advantages for carrying out electrochemical operations which may also proceed in presence of water. Thus the migration velocities of the ions are higher in ammonia than in Water, which renders solutions in anhydrous ammonia particularly available for electrochemical Work. Further, certain metalsfsuch, for instance, as iron and zinc-Which can be deposited from aqueous solutions are obtainable with less eX- pense, in a better physical state, and in a condition of' higher purity when separated from solutions of their salts in ammonia. I have separated sodium, potassium, magnesium, chromium, iron, and silver by following methods similar to that described for magnesium, and there appears to be no reason Why many other metals cannot be so produced. The process can also be used for the electrolytic refining of metals in like manner as-it is done with those metals which are now purifiedby electrolysis in aqueous'solution. Thus I have purified iron by immersing an iron cathode and an iron anode containing silicon and carbon in a solution of iron cyanid and potassium cyanide in ammonia, and on passing current have obtained pure iron on the cathode, the carbon and silicon not being dissolved at the anode. The obtaining of pure iron is a valuable commercial application of the process, since pure iron is now very costly, but very desirable for the production of' grades of iron and steel free from phosphorus and other deleterious impurities.
I claimn l. The method of' electrolysis, which consists in passing an electric current through a solution of a compound in anhydrous ammonia.
2. The method of separating metal electrolytically, which consists in passing an electric current through a solution of' a'compound of such metal in anhydrous ammonia.
3. The method of separating metal electrolytically, which consists in passing an electric current through a solution of an anhydrous salt of such metal in anhydrous ammonia.
4. The method of' separating metal electrolytically, which consists in passing an electric current through a solution of an anhydrous salt of such metal in anhydrous ammonia, a porous diaphragm being interposed between the electrodes.
5. The method of separating magnesium electrolytically, which consists in passing an electric current through a solution of a compound of' magnesium in anhydrous ammonia.
6. The method of' separating'metal electrolytically, which consists in passing an electric current through a solution of a compound of' such metal in anhydrous ammonia, and applying a refrigerating medium to the solution to prevent or retard evaporation of the solvent.
7. The method of refining metals, Which consists in electrolyzing a solution of the salt of the metal to be refined in anhydrous ainmonia, by the passage of the current through such solution, using as an anode a mass ot' the metal containing impurities of such a nature that all of them will remain undissolved or if dissolved will remain in solution, the pure metal only being deposited on the cathode.
In testimony whereof' I have hereunto set my hand.
WILLIAM HOOPES.
Witnesses:
JOHN MILLER, H. M. CORWIN.
US23488604A 1904-11-30 1904-11-30 Method of electrolytic separation. Expired - Lifetime US788315A (en)

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Cited By (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2615838A (en) * 1946-05-27 1952-10-28 G And W H Corson Inc Electrolytic process of producing alkali and alkaline earth metals
US3069334A (en) * 1957-06-12 1962-12-18 Ziegler Karl Process for the production of tetraethyl lead
US3131135A (en) * 1961-01-23 1964-04-28 Standard Oil Co Electrolysis of alkyl grignardcontaining electrolytes
US4091152A (en) * 1973-08-16 1978-05-23 P.R. Mallory & Co. Inc. Lithium SO2 cell

Cited By (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2615838A (en) * 1946-05-27 1952-10-28 G And W H Corson Inc Electrolytic process of producing alkali and alkaline earth metals
US3069334A (en) * 1957-06-12 1962-12-18 Ziegler Karl Process for the production of tetraethyl lead
US3131135A (en) * 1961-01-23 1964-04-28 Standard Oil Co Electrolysis of alkyl grignardcontaining electrolytes
US4091152A (en) * 1973-08-16 1978-05-23 P.R. Mallory & Co. Inc. Lithium SO2 cell

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