US2595387A - Method of electrolytically recovering nickel - Google Patents

Method of electrolytically recovering nickel Download PDF

Info

Publication number
US2595387A
US2595387A US649370A US64937046A US2595387A US 2595387 A US2595387 A US 2595387A US 649370 A US649370 A US 649370A US 64937046 A US64937046 A US 64937046A US 2595387 A US2595387 A US 2595387A
Authority
US
United States
Prior art keywords
leaching
nickel
cathode
sulphuric acid
anode
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Expired - Lifetime
Application number
US649370A
Inventor
Kalling Bo Michael Sture
Sundgren-Wallden Ruth Mariana
Wallden Sven Johan
Sivander Karl Arne
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Bolidens Gruvaktiebolag
Original Assignee
Bolidens Gruvaktiebolag
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Bolidens Gruvaktiebolag filed Critical Bolidens Gruvaktiebolag
Application granted granted Critical
Publication of US2595387A publication Critical patent/US2595387A/en
Anticipated expiration legal-status Critical
Expired - Lifetime legal-status Critical Current

Links

Images

Classifications

    • 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
    • C25C1/06Electrolytic production, recovery or refining of metals by electrolysis of solutions or iron group metals, refractory metals or manganese
    • C25C1/08Electrolytic production, recovery or refining of metals by electrolysis of solutions or iron group metals, refractory metals or manganese of nickel or cobalt

Definitions

  • the present invention relates to a method for recovering the metals of the iron group particularly nickel and cobalt or salts of these metals from materials containing said metals, by leaching with acid solutions and electrolysis of said solutions.
  • the leaching is preferably performed by using sulphurous acid solutions and the electrolysis is carried out under such conditions that the anolyte may be used for leaching said material containing said metals.
  • the leaching method or the electrolytic method may of course be used in any suitable or known metal recovering process without using the other method.
  • Necessary sulphurous anhydride may usually be available in the form of fluegas containing sulphurous anhydride.
  • the combined leaching and electrolytic process according to the invention give over the processes in which the electrolysis is performed with a soluble anode consisting in raw metal among others the great advantage that any impurities do not enter the electrolytic cell whereby an unlimitedly pure metal may be produced.
  • the leaching according to the invention is substantially characterized in that materials containing metallic nickel and/or cobalt are leached with a solution of sulphurous acid or a solution containing sulphurous acid, for instance in such a manner that sulphurous anhydride is allowed to bubble through the leaching liquor.
  • the metal is dissolved considerably more rapidly and more completely in sulphurous anhydride containing solutions than in for instance sulphuric acid, which involves an essentially increased production by the leaching apparatus.
  • a suitable basic material for the production of nickel is e. g. nickel copper sponge, produced from nickel copper concentration matte.
  • the invention is not limited to the leaching of reduced metal sponge, but comprises leaching nickel and cobalt containing products generally by the addition of sulphurous anhydride.
  • nickel may be recovered directly from nickel copper concentration matte of low sulphur content (ratio Cu:S about 4:1) by means of leaching with a sulphurous acid solution.
  • a great part (about of the nickel content of the mattenot completely corresponding to the nickel which is present in metallic formis leached comparatively rapidly.
  • the leaching then takes place essentially slower. If the concentration matte converting is controlled so that all the nickel may be considered to be present in metallic form the yield during the 4first rapid leaching step may be increased in a corresponding degree. In this case, however, the amount of nickel which is scoried in the concentration matte converting and which must be returned to the matte furnace will be considerable. The leaching is facilitated if the concentration matte is present in granulated form.
  • Dissolving pure metallic nickel and cobalt or leaching other products containing said metals is also advantageously carried out by means of solutions containing sulphurous acid.
  • the electrolysis according to the invention is carried out by means of an insoluble anode in a diaphragm cell.
  • the electrolyte is introduced into the cathode chamber as a neutral or slightly acid salt solution for instance a sulphate solution and is allowed to flow through the diaphragm into the anode chamber at such a velocity that the catholyte remains slightly acid and the anolyte so highly acid that it may be used for leaching purposes.
  • the acid liquor is purified after the leaching and returned to the cathode chamber.
  • An insoluble anode is used for the electrolysis of a solution, which, by a separate operation, has been completely freed from impurities.
  • the catholyte and the anolyte both are pure a cathode metal of unlimited degree of purity can be produced independent of the velocity of now being correctly controlled or of possibly occurring .f
  • the permeability of the diaphragm will be constant, and therefore the velocity of now may be easily controlled by arranging the level of the liquid in the cathode chamber somewhat higher than that in the anode chamber.
  • the cheapest acid for the process is normally sulphuric acid.
  • the content of acid in the cathode chamber is maintained at 0.5 to 1.5 grams per liter, whereby the content of acid in the anode chamber will amount to to 100 grams per liter depending on the quality of the diaphragm.
  • the current yield will range from 70% to 90%.
  • a salt solution containing nonprecipitable metal ions, preferably alkaline ions
  • the pH of the catholyte may be allowed to rise above 6 without any risk for basic precipitations in the bordering layer at the cathode surface.
  • the admitted range of acidity will increase, and the control of the velocity of ow will be facilitated.
  • Sodium or ammonium sulphates are-suitable alkaline salts.
  • salts of magnesium and aluminium may be used.
  • the most suitable material for the diaphragm is nitrated fabric of cellulose fibre, for instance cotton, cellulose or staple fibre. Fabric of silicate fibre, for instance glass wool fabric or stone Wool fabric mayfalso be used.
  • the diaphragm may consist also of ceramic plates.
  • the exit anolyte may contain a sufficiently great amount of acid, as to admit of a rational leaching process such as leaching metal sponge in counter current or leaching other soluble forms of metals or metal compounds.
  • the electrolysis according to the invention relates to the recovery of the metals of the iron group from their ores, but, of course, it may be applied also in the recovery of other basic materials and in surface treatment in an electrolytic way.
  • a method of recovering nickel from materials containing said nickel in its metallic state that comprises leaching said materials with a leaching liquor containing sulphuric acid and sulphurous anhydride, electrolyzing the resulting nickel-containing leaching liquor by passing it into the cathode chamber of an electrolytic cell in the form of a sulphate solution containing no more than about 1.5 grams of sulphuric acid per liter, the eiectrolytic cell containing an insoluble anode and a coarse, porous diaphragm that will permit the flow of electrolyte between the cathode and anode compartments, causing the leaching liquor to flow from the cathode to the anode compartment of the cell at a velocity such as will maintain the liquor in the cathode compartment at not more than around 1.5 grams of sulphuric acid per liter but will raise the acidity of the leaching liquor in the anode compartment to around 25 to 100 grams of sulphuric acid per liter, withdrawing leaching liquor
  • a method as defined in claim l further characterized in that the material to be leached is a nickel concentration matte having a low sulphur content.
  • a method as defined in claim 1 further characterizedinthat the material to be leached is a nickel concentration matte containing about four times as muchv copper as sulphur.

Description

May 6, 1952 B. M. s. KALLING ET AL 2,595,387
METHOD OF ELECTROLYTICALLY RECOVERING NICKEL med Feb. 21, 1946 www, @we @VM ATTORNEYS Patented May 6, 19x52 METHOD OF ELECTROLYTICALLY RECOVERING NICKEL Bo Michael Sture Kalling, Domnarvet, Ruth Saga Mariana Sundgren-Walldn and Sven Johan Walldn, Stockholm, and Karl Arne Sivander, Perstorp, Sweden, assignors to Bolidens Gruvaktiebolag, Stockholm, Sweden, a joint-stock company limited of Sweden Application February 21, 1946, Serial No. 649,370 In Sweden December 5, 1942 Section 1, Public Law 690, August 8, 1946 Patent expires December 5, 1962 3 Claims. 1
The present invention relates to a method for recovering the metals of the iron group particularly nickel and cobalt or salts of these metals from materials containing said metals, by leaching with acid solutions and electrolysis of said solutions. The leaching is preferably performed by using sulphurous acid solutions and the electrolysis is carried out under such conditions that the anolyte may be used for leaching said material containing said metals.
The leaching method or the electrolytic method may of course be used in any suitable or known metal recovering process without using the other method.
A great number of methods for recovering especially nickel by means of electrolysis in a cell with insoluble anode has hitherto been proposed but never obtained any greater technical importance due to the fact that the solution adjacent to the cathode must be substantially neutral. On account hereof neutralizing agents such as nickel hydrate must be added during the electrolysis if a diaphragm cell be not used. On the other hand an employment of an ordinary diaphragm cell With a compact diaphragm involves the usual diiiculties in lling up the pores of the diaphragm. According to this invention a comparatively coarse porous diaphragm is used which readily can be cleaned in case that the pores would be lled up. As great an obstacle for the technical use of the electrolytic process with insoluble anode has been the great diiiiculties to dissolve the metal by means of the slightly acid electrolytes from basic materials of average content or metallurgical intermediate products. Thus it has for instance been necessary to leach the basic material with strong acids and precipitate metal hydrate from the solution by neutralizing agents and use metal hydrate as neutralizing agents forthe exit electrolyte. According to our invention we obtain in the electrolysis a comparatively strong acid exit electrolyte which after sulphurous anhydride being added to it is an excellent solvent for metal in the basic material. Thus a rational leaching and electrolytic process is possible in which the consumption of chemical agents is very low. Necessary sulphurous anhydride may usually be available in the form of fluegas containing sulphurous anhydride. The combined leaching and electrolytic process according to the invention give over the processes in which the electrolysis is performed with a soluble anode consisting in raw metal among others the great advantage that any impurities do not enter the electrolytic cell whereby an unlimitedly pure metal may be produced.
The leaching according to the invention is substantially characterized in that materials containing metallic nickel and/or cobalt are leached with a solution of sulphurous acid or a solution containing sulphurous acid, for instance in such a manner that sulphurous anhydride is allowed to bubble through the leaching liquor. The metal is dissolved considerably more rapidly and more completely in sulphurous anhydride containing solutions than in for instance sulphuric acid, which involves an essentially increased production by the leaching apparatus. Thus it is possible to obtain leaching yields which cannot be attained in a reasonable time in leaching with other liquors. A suitable basic material for the production of nickel is e. g. nickel copper sponge, produced from nickel copper concentration matte. On account of the reducing effect of the sulphurous anhydride oxidation and dissolving of copper from the sponge are prevented. As leaching liquor in the production of nickel one ordinarily uses the exit electrolyte from the subsequent nickel electrolysis, containing for instance 25 grams sulphuric acid per liter. To said electrolyte is added as great an amount of sulphurous anhydride as is necessary to make up the loss of acid in the process. Nickel sulphite and excess of sulphurous anhydride are oxidized by air into sulphate and sulphuric acid.
The invention is not limited to the leaching of reduced metal sponge, but comprises leaching nickel and cobalt containing products generally by the addition of sulphurous anhydride.
Thus nickel may be recovered directly from nickel copper concentration matte of low sulphur content (ratio Cu:S about 4:1) by means of leaching with a sulphurous acid solution. A great part (about of the nickel content of the mattenot completely corresponding to the nickel which is present in metallic formis leached comparatively rapidly. The leaching then takes place essentially slower. If the concentration matte converting is controlled so that all the nickel may be considered to be present in metallic form the yield during the 4first rapid leaching step may be increased in a corresponding degree. In this case, however, the amount of nickel which is scoried in the concentration matte converting and which must be returned to the matte furnace will be considerable. The leaching is facilitated if the concentration matte is present in granulated form.
Dissolving pure metallic nickel and cobalt or leaching other products containing said metals is also advantageously carried out by means of solutions containing sulphurous acid.
The electrolysis according to the invention is carried out by means of an insoluble anode in a diaphragm cell. The electrolyte is introduced into the cathode chamber as a neutral or slightly acid salt solution for instance a sulphate solution and is allowed to flow through the diaphragm into the anode chamber at such a velocity that the catholyte remains slightly acid and the anolyte so highly acid that it may be used for leaching purposes. The acid liquor is purified after the leaching and returned to the cathode chamber.
An insoluble anode is used for the electrolysis of a solution, which, by a separate operation, has been completely freed from impurities. As the catholyte and the anolyte both are pure a cathode metal of unlimited degree of purity can be produced independent of the velocity of now being correctly controlled or of possibly occurring .f
damages of the diaphragm. If the velocity of ow is too low or if the diaphragm is damaged the development of hydrogen gas Will increase and the defect may be easily observed and repaired. Even under such abnormal conditions a good cathode metal is obtained but the current yield is not optimal. In case of too high a velocity of iiow the acid content of the anolyte will decrease so that metalliferous material cannot be satisfactorily leached by the exit electrolyte and if no special steps be taken, the catholyte may be neutral, whereby basic salts deposit on the cathode. If a moderate average current yield will satisfy, the velocity of flow may be allowed to vary in a comparatively wide range. As no precipitations or solids occur in the electrolyte the permeability of the diaphragm will be constant, and therefore the velocity of now may be easily controlled by arranging the level of the liquid in the cathode chamber somewhat higher than that in the anode chamber. The cheapest acid for the process is normally sulphuric acid. In the electrolysis of for instance a pure nickel sulphate solution containing 50 grams nickel per liter at a temperature of 60 C. the content of acid in the cathode chamber is maintained at 0.5 to 1.5 grams per liter, whereby the content of acid in the anode chamber will amount to to 100 grams per liter depending on the quality of the diaphragm. Thus the current yield will range from 70% to 90%. If a salt solution, containing nonprecipitable metal ions, preferably alkaline ions, is added to a nickel sulphate solution the pH of the catholyte may be allowed to rise above 6 without any risk for basic precipitations in the bordering layer at the cathode surface. With such an admixture the admitted range of acidity will increase, and the control of the velocity of ow will be facilitated. Besides, it Will be possible to essentially increase the average current yield. At a pH about 6 a current yield of 95%-100% will be obtained. Sodium or ammonium sulphates are-suitable alkaline salts. Also salts of magnesium and aluminium may be used.
In; the electrolysis of a pure cobalt sulphate solution one may allow the pH to rise very much, for instance to pH 6 without running any risk of basic precipitations in the bordering layer of the cathode. The current yield may easily be raised to %-100%.
The most suitable material for the diaphragm is nitrated fabric of cellulose fibre, for instance cotton, cellulose or staple fibre. Fabric of silicate fibre, for instance glass wool fabric or stone Wool fabric mayfalso be used. The diaphragm may consist also of ceramic plates.
According to the present invention the exit anolyte may contain a sufficiently great amount of acid, as to admit of a rational leaching process such as leaching metal sponge in counter current or leaching other soluble forms of metals or metal compounds.
Primarily the electrolysis according to the invention relates to the recovery of the metals of the iron group from their ores, but, of course, it may be applied also in the recovery of other basic materials and in surface treatment in an electrolytic way.
As mentioned above and as will appear from the detailed description above of the leaching and electrolytic processes said processes may be used in combination with each other constituting a complete metal recovering process. The scope of the invention is, however, not limited to this combination but the improved leaching and the electrolytic methods may also be used separately or combined with any known or suitable method or methods for recovering metals or metal salts.
Having thus described our invention we declare that what we claim is:
l. A method of recovering nickel from materials containing said nickel in its metallic state that comprises leaching said materials with a leaching liquor containing sulphuric acid and sulphurous anhydride, electrolyzing the resulting nickel-containing leaching liquor by passing it into the cathode chamber of an electrolytic cell in the form of a sulphate solution containing no more than about 1.5 grams of sulphuric acid per liter, the eiectrolytic cell containing an insoluble anode and a coarse, porous diaphragm that will permit the flow of electrolyte between the cathode and anode compartments, causing the leaching liquor to flow from the cathode to the anode compartment of the cell at a velocity such as will maintain the liquor in the cathode compartment at not more than around 1.5 grams of sulphuric acid per liter but will raise the acidity of the leaching liquor in the anode compartment to around 25 to 100 grams of sulphuric acid per liter, withdrawing leaching liquor from the anode compartment and returning it to the leaching step of the process.
2. A method as defined in claim l further characterized in that the material to be leached is a nickel concentration matte having a low sulphur content.
3. A method as defined in claim 1 further characterizedinthat the material to be leached is a nickel concentration matte containing about four times as muchv copper as sulphur.
MICHAEL STURE KALLING. RUTH SAGA MARIANA SUNDGREN- WALLDEN. SVEN JOHAN WALLDE'N.
KARL ARNE srvANDER.
(References on following page) REFERENCES CITED l UNITED STATES PATENTS Number Name Date Strap Oct. 4, 1892 Ramage Apr. 25, 1905 Wilcox May 16, 1905 Farnham Oct. 24, 1911 Ramage Oct. 31, 1911 Udy Apr. 13, 1920 Haglund Apr. 19, 1921 Heberlen Sept. 6, 1921 Hybinette Nov. 1, 1921 Number 6 Name Date Langer -1-- M89, 2, 1922 Greenwalt Mar. 3, 1925 Hybinette Mar; 16, 1926 DAns Aug. 18, 1931 Hybinette Feb. 16, 1932 Peek et a1. Nov. 8, 1932 Keyes Sept. 13, 1938 Allen Oct. 19, 1948 OTHER REFERENCES Fedotov, Extraction of Pure Cobalt by Electrolysis, Electrochemical Society Reprint No. 87-3, April 16, 1945.

Claims (1)

1. A METHOD OF RECOVERING NICKEL FROM MATERIALS CONTAINING SAID NICKEL IN ITS METALLIC STATE THAT COMPRISES LEACHING SAID MATERIALS WITH A LEACHING LIQUOR CONTAINING SULPHURIC ACID AND SULPHUROUS ANHYDRIDE, ELECTROLYZING THE RESULTING NICKEL-CONTAINING LEACHING LIQUOR BY PASSING IT INTO THE CATHODE CHAMBER OF AN ELECTROLYTIC CELL IN THE FORM OF A SULPHATE SOLUTION CONTAINING NO MORE THAN ABOUT 1.5 GRAMS OF SULPHURIC ACID PER LITER, THE ELECTROLYTIC CELL CONTAINING AN INSOLUBLE ANODE AND A COARSE, POROUS DIAPHRAGM THAT WILL PERMIT THE FLOW OF ELECTROLYTE BETWEEN THE CATHODE AND ANODE COMPARTMENTS, CAUSING THE LEACHING LIQUOR TO FLOW FROM THE CATHODE TO THE ANODE COMPARTMENT OF THE CELL AT A VELOCITY SUCH AS WILL MAINTAIN THE LIQUOR IN THE CATHODE COMPARTMENT AT NOT MORE THAN AROUND 1.5 GRAMS OF SULPHURIC ACID PER LITER BUT WILL RAISE THE ACIDITY OF THE LEACHING LIQUOR IN THE ANODE COMPARTMENT TO AROUND 25 TO 100 GRAMS OF SULPHURIC ACID PER LITER, WITHDRAWING LEACHING LIQUOR FROM THE ANODE COMPARTMENT AND RETURNING IT TO THE LEACHING STEP OF THE PROCESS.
US649370A 1942-12-05 1946-02-21 Method of electrolytically recovering nickel Expired - Lifetime US2595387A (en)

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
SE2595387X 1942-12-05

Publications (1)

Publication Number Publication Date
US2595387A true US2595387A (en) 1952-05-06

Family

ID=20426436

Family Applications (1)

Application Number Title Priority Date Filing Date
US649370A Expired - Lifetime US2595387A (en) 1942-12-05 1946-02-21 Method of electrolytically recovering nickel

Country Status (1)

Country Link
US (1) US2595387A (en)

Cited By (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3506550A (en) * 1966-10-24 1970-04-14 St Joseph Lead Co Electrolytic process of recovering nickel and cadmium from spent battery plates
US4214964A (en) * 1978-03-15 1980-07-29 Cannell John F Electrolytic process and apparatus for the recovery of metal values
US4484990A (en) * 1980-06-16 1984-11-27 Minnesota Mining And Manufacturing Company Mist suppressant for solvent extraction metal electrowinning
US4600483A (en) * 1984-11-19 1986-07-15 Chevron Research Company Electrolytic reduction of cobaltic ammine
DE19653273A1 (en) * 1996-12-20 1998-06-25 Lpw Anlagen Gmbh Recovery of at least one of the metals precipitated onto a substrate

Citations (17)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US483639A (en) * 1892-10-04 Jules strap
US788064A (en) * 1905-01-31 1905-04-25 Alexander S Ramage Utilizing spent pickle liquor.
US790238A (en) * 1905-03-06 1905-05-16 Esmeralda Copper Precipitating Company Method of recovering copper from its ores.
US1006836A (en) * 1911-08-11 1911-10-24 Nat Tube Co Process and apparatus for electrolytic recovery of waste liquor.
US1007388A (en) * 1911-03-07 1911-10-31 Alexander S Ramage Electrolytic method of refining iron.
US1336765A (en) * 1919-08-14 1920-04-13 Haynes Stellite Co Process of recovering cobalt
US1375631A (en) * 1918-12-05 1921-04-19 Haglund Gustaf Process of separating and refining metals
US1389829A (en) * 1918-12-07 1921-09-06 Heberlein Christian Method of electrolyzing a solution of nickel salt
US1395827A (en) * 1920-02-16 1921-11-01 Hybinette Noak Victor Separating metals by electrolysis
US1414423A (en) * 1921-04-11 1922-05-02 Langer Carl Electrolytic separation of metals
US1528209A (en) * 1923-09-21 1925-03-03 William E Greenawalt Metallurgical process
US1577422A (en) * 1921-01-13 1926-03-16 Anglo Canadian Mining And Refi Refining copper-nickel matte, etc.
US1819770A (en) * 1927-05-23 1931-08-18 Gasgluhlicht Auer Gmbh Deutsch Process for decomposing ores of the rare earths, of zirconium and titanium, in a cycle by means of sulphuric acid
US1844937A (en) * 1928-06-28 1932-02-16 Hybinette Noak Victor Process of electrolytic copper refining
US1887037A (en) * 1930-08-15 1932-11-08 Int Nickel Co Process of refining nickel bearing materials
US2130278A (en) * 1934-09-01 1938-09-13 Harmon E Keyes Leaching-precipitation-flotation process
US2451647A (en) * 1944-12-21 1948-10-19 Manganese Products Inc Process of treating intermediate manganese siliceous ores

Patent Citations (17)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US483639A (en) * 1892-10-04 Jules strap
US788064A (en) * 1905-01-31 1905-04-25 Alexander S Ramage Utilizing spent pickle liquor.
US790238A (en) * 1905-03-06 1905-05-16 Esmeralda Copper Precipitating Company Method of recovering copper from its ores.
US1007388A (en) * 1911-03-07 1911-10-31 Alexander S Ramage Electrolytic method of refining iron.
US1006836A (en) * 1911-08-11 1911-10-24 Nat Tube Co Process and apparatus for electrolytic recovery of waste liquor.
US1375631A (en) * 1918-12-05 1921-04-19 Haglund Gustaf Process of separating and refining metals
US1389829A (en) * 1918-12-07 1921-09-06 Heberlein Christian Method of electrolyzing a solution of nickel salt
US1336765A (en) * 1919-08-14 1920-04-13 Haynes Stellite Co Process of recovering cobalt
US1395827A (en) * 1920-02-16 1921-11-01 Hybinette Noak Victor Separating metals by electrolysis
US1577422A (en) * 1921-01-13 1926-03-16 Anglo Canadian Mining And Refi Refining copper-nickel matte, etc.
US1414423A (en) * 1921-04-11 1922-05-02 Langer Carl Electrolytic separation of metals
US1528209A (en) * 1923-09-21 1925-03-03 William E Greenawalt Metallurgical process
US1819770A (en) * 1927-05-23 1931-08-18 Gasgluhlicht Auer Gmbh Deutsch Process for decomposing ores of the rare earths, of zirconium and titanium, in a cycle by means of sulphuric acid
US1844937A (en) * 1928-06-28 1932-02-16 Hybinette Noak Victor Process of electrolytic copper refining
US1887037A (en) * 1930-08-15 1932-11-08 Int Nickel Co Process of refining nickel bearing materials
US2130278A (en) * 1934-09-01 1938-09-13 Harmon E Keyes Leaching-precipitation-flotation process
US2451647A (en) * 1944-12-21 1948-10-19 Manganese Products Inc Process of treating intermediate manganese siliceous ores

Cited By (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3506550A (en) * 1966-10-24 1970-04-14 St Joseph Lead Co Electrolytic process of recovering nickel and cadmium from spent battery plates
US4214964A (en) * 1978-03-15 1980-07-29 Cannell John F Electrolytic process and apparatus for the recovery of metal values
US4484990A (en) * 1980-06-16 1984-11-27 Minnesota Mining And Manufacturing Company Mist suppressant for solvent extraction metal electrowinning
US4600483A (en) * 1984-11-19 1986-07-15 Chevron Research Company Electrolytic reduction of cobaltic ammine
DE19653273A1 (en) * 1996-12-20 1998-06-25 Lpw Anlagen Gmbh Recovery of at least one of the metals precipitated onto a substrate
DE19653273C2 (en) * 1996-12-20 2000-09-14 Lpw Anlagen Gmbh A method for recovering at least one metal deposited on a substrate

Similar Documents

Publication Publication Date Title
CN108622943B (en) A method of with useless nickel cobalt (alloy) production LITHIUM BATTERY nickel sulfate and cobaltous sulfate
US4002544A (en) Hydrometallurgical process for the recovery of valuable components from the anode slime produced in the electrolytical refining of copper
CN110468279A (en) A method of recycling lead from the lead plaster material of waste lead storage battery
US2595387A (en) Method of electrolytically recovering nickel
CN102628105B (en) Method for comprehensively recycling and using baric waste slag in refined aluminum production process
US5181994A (en) Process for the preparation of chromic acid
US3414494A (en) Method of manufacturing pure nickel hydroxide
Archibald et al. The Kristiansand nickel refinery
US2331395A (en) Electrolytic recovery of metals
US1577422A (en) Refining copper-nickel matte, etc.
US2771413A (en) Electrodeposition of chromium
RU2146720C1 (en) Method of processing secondary materials
US1887037A (en) Process of refining nickel bearing materials
US2385269A (en) Process of electrolytically extracting metal
US1844937A (en) Process of electrolytic copper refining
US3707448A (en) Method for extracting metal from a metal source in an electrolytic cell
US1375631A (en) Process of separating and refining metals
CN108298564A (en) A method of it is crystallized using electrodeposition lean solution production vulcanized sodium
US1569137A (en) Refining of copper-nickel matte
US2446313A (en) Process for production of electrolytic manganese
US2650192A (en) Electrowinning of chromium
US1878918A (en) Manufacture of chromic acid
US2771414A (en) Method of making electrolytic chromium
US1620580A (en) Metallurgy of tin
US2816007A (en) Method of extracting lithium from its silico-aluminous ores