US1608706A - Electrodeposition of metals - Google Patents
Electrodeposition of metals Download PDFInfo
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- US1608706A US1608706A US292793A US29279319A US1608706A US 1608706 A US1608706 A US 1608706A US 292793 A US292793 A US 292793A US 29279319 A US29279319 A US 29279319A US 1608706 A US1608706 A US 1608706A
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- nickel
- bath
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- hydrate
- electrodeposition
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- C—CHEMISTRY; METALLURGY
- C25—ELECTROLYTIC OR ELECTROPHORETIC PROCESSES; APPARATUS THEREFOR
- C25D—PROCESSES FOR THE ELECTROLYTIC OR ELECTROPHORETIC PRODUCTION OF COATINGS; ELECTROFORMING; APPARATUS THEREFOR
- C25D3/00—Electroplating: Baths therefor
- C25D3/02—Electroplating: Baths therefor from solutions
- C25D3/12—Electroplating: Baths therefor from solutions of nickel or cobalt
-
- C—CHEMISTRY; METALLURGY
- C25—ELECTROLYTIC OR ELECTROPHORETIC PROCESSES; APPARATUS THEREFOR
- C25D—PROCESSES FOR THE ELECTROLYTIC OR ELECTROPHORETIC PRODUCTION OF COATINGS; ELECTROFORMING; APPARATUS THEREFOR
- C25D13/00—Electrophoretic coating characterised by the process
- C25D13/02—Electrophoretic coating characterised by the process with inorganic material
Definitions
- My invention relates to a method and means of electro-depositing metals, particularly the nickel metals, by which I mean nickel, or cobalt, or alloys containing either nickel or cobalt or both of these metals.
- My invention aims to produce a new bath and a new method of employing said bath, whereby I am enabled to electrodeposit said nickel metals at a..,very high rate, using very high current densities.
- I am further enabled to substantially avoid pitting or pits in the deposits.
- said nickel metals may be obtained in a dense, ceremoniesne, homogeneous, malleable and ductile condition. Said nickel metals deposited in accordance with my invention,
- This bath is preferably operated at a temperature of about 130 F. Except for the addition of boric acid, as set forth above, the bath should be neutral.
- the anode may consist of cast or rolled nickel, and the oath- Ode of a metal, such as aluminum or nickel, which is adapted to receive a smooth, separable deposit of the electrodeposited nickel. However, if so desired, the metal may be electrodeposited adherently, as'in the form of a plating.
- the cathode on which the nickel is eing electrodeposited is intermittently or periodically exposed to a gas eous medium, such as the air, as by removal from the bath or otherwise.
- a gas eous medium such as the air
- the time during which the cathode and the electrode-' posited nickel carried by it are kept out of the bath should be more than what I term the minimum or hydrogen dissipation period, which is necessary to permit the hydrogen deposited with the metal to be dissipated or removed by contact with the surrounding gaseous medium, such as the air.
- Th s minimum or hydrogen dissipation period may be readily determined by trial and experiment and is generally greater than about one second, usually two seconds.
- the time during which the cathode and the deposit carried by it are kept out of the bath should not, however, exceed what I term the maximum or critical or separable deposit period, which, in the case here given, is from about 6 to about '16 seconds, by which I mean that if the time during which the cathode and its deposit are kept out of thebath exceeds the said max imum or critical or separable deposit per od, on restoring the cathode and its deposit to the bath, the succeeding deposit will not be. adherent but will separate or be eas ly separable from the previous deposit. Thisresults in a laminated, weak metal, a condition which is obviously'to be avoided, where a sound unitary metal is desired.
- the frequency of removal or exposure frequency period is determined by the factors of deposition which influence hydrogen liberation, such as the degree of exactness of neutrality, current density, and temperature. I have found that in the bath here described by way of example, and operating at a temperature of about 130 F., and with a current density of about 10 amperes per square decimeter, this period may be from 1 to 2 minutes.
- the electrodeposited metal such as the nickel in the example given
- the electrodeposited metal may not only be dense, ceremoniesne and free from pores and hydrogen, but in order also that said metal shall be free from what are known as pits in' the art of the deposition of the nickel metals
- salts such as the sulphates, of the alkali metals, preferably sodium, finely divided or colloidal nickel hydrate is produced and held in suspension in the bath.
- This freshly and continuously produced hydrate replenishes the hydrate which during the operation of the bath aggregates or for other reasons goes out of suspension and drops to the bottom of the bath.
- Such salts have further beneficial effects and greatly improve the operation of the bath and the character of the deposits formed.
- I may add varying amounts, such as from about 1 to about 10 grams, preferably 1 gram, of sodium sulphate for each liter of bath solution.
- colloid-producing substance such as the sodium sulphate
- caustic soda or sodium hydroxide is to produce by and during electrodeposition, some caustic soda or sodium hydroxide.
- the caustic soda or sodium hydroxide thus produced, by interaction with the nickel salts present in the bath, such as the nickel sulphate, generates finely divided or colloidal nickel hydrate which remains suspended in the bath. The interaction at the same time re-generates the sodium sulphate.
- the sodium sulphate or its equivalent also acts to assist the deposition and to improve the character of the deposit,-
- Figure 1 is a cross section
- Figure 2 is a longitudinal section apparatus.
- vat 1 for containing the bath 2.
- 3 is the anode and 4 the connector forsupplying said anode with current.
- the cathode is indicated at 5 and its conductor at 6.
- any suitable means which may, if desired be manually operated, for intermittently or periodically removing the cathode from the bath, as set forth above.
- the resulting product as in the case of nickel in the illustrative embodiment set forth above, is, as before stated, dense, ceremoniesne, homogeneous, malleable and ductile.
- the new nickel herein described is substantially free from pores and pits and contains no appreciable amount of hydro 1 1.
- the nickel herein described differs in character from the nickel obtained by the usual metallurgical processes in that my new nickel is free from the usual poisonous contents such as sulphur, silicon, arsenic, carbon, carbides, oxygen, and other gases, and oxide containing compounds, generally present in metallurglcal nickel and rendering the same imperfect and more difficult to work. Furthermore, my new nickel is to be further differentiated from the ordinary metallur'gical nickel in that it has a finer and more even grain than such metallurgical nickel, as is shown by metallographic micro-photographs. It is also considerably purer than such metallurgical nickel, resists chemical action better and has ahigher melting point.
- the nickel described herein is also to be differentiated from the usual electrodeposited nickel in that it is substantially free from pores, pits and hydrogen, and is malleable and ductile to a' very high degree, unlike the usual electrodeposited nickel which is porous, contains a large hydrogen content and is brittle and unworkable
- a further diflerence in character between my new nickel and the ordinary metallurgical nickel is shown by the fact that the film of oxide formed by heating my new nickel in an oxidizing atmosphere is thinner, finer in texture and more adherent and flexible than the oxide coating formed by similar treatment of ordinary metallurgical nickel.
- oxide coating in the case of my new nickel is of a different color, generally yellow to brown, while the oxide coating on the metallurgical nickel is generallyviolet or indigo in color.
- a bath comprising a salt of a nickel metal in solution, and a finely divided hydrate of a nickel metal in suspension therein.
- a bath comprising, in solution, a salt of nickel, and an agent adapted during electrodeposition to produce a finely divided hydrate of nickel in suspension in the bath.
- a bath comprising, in suspension, finely divided nickel hydrate, and, in solution, a salt of nickel, and an agent adapted during electrodeposition to produce a finely divided hydrate of nickel in suspension in the bath.
- a method of electrodepositing nickel metals which comprises intermittently electrodepositing a nickel metal on the cathode from a bath containing, in solution, a chloride of a nickel metal an a ent adapted during deposition to provide a nely divided hydrate of a nickel metal in suspension in said bath, and boric acid, and, insuspension, a finely divided hydrate of a nickel metal, and successively bringing .the surfaces of the successive deposits into contact with a gaseous medium for a period of time sufficiently long to permit the hydrogen in the deposited surfaces to be dissipated, but
Description
Nov. 30 1926. 1,608,706
- c. P. MADSEN ELECTRODEPOSITION OF METALS Original Filed April 26. 1919 Patented Nov. 30, 1926.
UNITED STATES PATENT OFFICE.
CHARLES P. MADSEN, OF NEW YQRK, N. Y., ASSIGN'OR T MADSENELL CORPORATION,
OF NEW YORK, N. Y., A CORPORATION OF NEW YORK.
ELECTRODEPOSITION OF METALS.
Application filed April 26, 1919, Serial No. 292,793. Renewed December 20, 1924.
My invention relates to a method and means of electro-depositing metals, particularly the nickel metals, by which I mean nickel, or cobalt, or alloys containing either nickel or cobalt or both of these metals. My invention aims to produce a new bath and a new method of employing said bath, whereby I am enabled to electrodeposit said nickel metals at a..,very high rate, using very high current densities. By means of my invention I am further enabled to substantially avoid pitting or pits in the deposits. By the use of my invention, moreover, said nickel metals may be obtained in a dense, reguline, homogeneous, malleable and ductile condition. Said nickel metals deposited in accordance with my invention,
are substantially free from pits, pores and hydrogen, and are workable to a remarkable de ree.
y way of example, I shall describe an illustrative embodiment of my invention in the following specification. I shall set forth my invention as applied more particularly to the electrodepositionof my new nickel, as described in my copending application Serial No. 292794, filed April 6, 1919, though it is of course to be understood that analogous means may be applied to the electrodeposition of the other nickel metals.
In producing the foregoing new nickel I may use an electrode osition bath of ap roximately the fol owing composition: lickel sulphate, 240 g.; nickel chloride, 20 g.; boric acid, 40 g.; water, 1 liter. This bath is preferably operated at a temperature of about 130 F. Except for the addition of boric acid, as set forth above, the bath should be neutral. The anode may consist of cast or rolled nickel, and the oath- Ode of a metal, such as aluminum or nickel, which is adapted to receive a smooth, separable deposit of the electrodeposited nickel. However, if so desired, the metal may be electrodeposited adherently, as'in the form of a plating.
During eposition the cathode on which the nickel is eing electrodeposited, is intermittently or periodically exposed to a gas eous medium, such as the air, as by removal from the bath or otherwise. The time during which the cathode and the electrode-' posited nickel carried by it are kept out of the bath should be more than what I term the minimum or hydrogen dissipation period, which is necessary to permit the hydrogen deposited with the metal to be dissipated or removed by contact with the surrounding gaseous medium, such as the air. Th s minimum or hydrogen dissipation period may be readily determined by trial and experiment and is generally greater than about one second, usually two seconds. The time during which the cathode and the deposit carried by it are kept out of the bath should not, however, exceed what I term the maximum or critical or separable deposit period, which, in the case here given, is from about 6 to about '16 seconds, by which I mean that if the time during which the cathode and its deposit are kept out of thebath exceeds the said max imum or critical or separable deposit per od, on restoring the cathode and its deposit to the bath, the succeeding deposit will not be. adherent but will separate or be eas ly separable from the previous deposit. Thisresults in a laminated, weak metal, a condition which is obviously'to be avoided, where a sound unitary metal is desired.
The frequency of removal or exposure frequency period is determined by the factors of deposition which influence hydrogen liberation, such as the degree of exactness of neutrality, current density, and temperature. I have found that in the bath here described by way of example, and operating at a temperature of about 130 F., and with a current density of about 10 amperes per square decimeter, this period may be from 1 to 2 minutes.
In order, moreover, that the electrodeposited metal, such as the nickel in the example given, may not only be dense, reguline and free from pores and hydrogen, but in order also that said metal shall be free from what are known as pits in' the art of the deposition of the nickel metals, I add to the bath, preferably before starting the electrodeposition, a quantity of finely divided nickel hydrate, preferably freshl precipitated nickel hydrate (NiO,H an probably existing in a colloidal condition, which nickel hydrate remains in suspension in the bath durin electrodeposition. While the quantity 0 hydrate so added may vary within considerable limits, I prefer to add from 1 to 5 grams, generally 1 gram, of said colloidal nickel hydrate to each liter of bath solution.
I have discovered that by adding to the bath certain salts, such as the sulphates, of the alkali metals, preferably sodium, finely divided or colloidal nickel hydrate is produced and held in suspension in the bath. This freshly and continuously produced hydrate replenishes the hydrate which during the operation of the bath aggregates or for other reasons goes out of suspension and drops to the bottom of the bath. Such salts have further beneficial effects and greatly improve the operation of the bath and the character of the deposits formed. For this purpose I may add varying amounts, such as from about 1 to about 10 grams, preferably 1 gram, of sodium sulphate for each liter of bath solution.
The action of the colloid-producing substance, such as the sodium sulphate, de-
scribed above, is to produce by and during electrodeposition, some caustic soda or sodium hydroxide. The caustic soda or sodium hydroxide thus produced, by interaction with the nickel salts present in the bath, such as the nickel sulphate, generates finely divided or colloidal nickel hydrate which remains suspended in the bath. The interaction at the same time re-generates the sodium sulphate. The sodium sulphate or its equivalent also acts to assist the deposition and to improve the character of the deposit,-
which factors are also further assisted by the initial addition of nickel hydrate in finely divided or colloidal condition to the bath.
In the accompanying drawing, I have diagrammatically illustrated a form of apparatus in which the foregoing illustrative embodiment of my invention may be carried out.
Referring to these drawings:
Figure 1 is a cross section; and
Figure 2 is a longitudinal section apparatus.
The apparatus oomprises briefly, a vat 1, for containing the bath 2. 3 is the anode and 4 the connector forsupplying said anode with current. The cathode is indicated at 5 and its conductor at 6. At 7 is indicated generall any suitable means, which may, if desired be manually operated, for intermittently or periodically removing the cathode from the bath, as set forth above.
7 The resulting product, as in the case of nickel in the illustrative embodiment set forth above, is, as before stated, dense, reguline, homogeneous, malleable and ductile. The new nickel herein described is substantially free from pores and pits and contains no appreciable amount of hydro 1 1.
It is, of course, to be understood hat where a deposit of cobalt, having the foregoing desirable properties,'is desired to be produced, a .cobaltanode is used in place of the nickel of such anode, and cobalt compounds are used in place of the corresponding nickel compounds. Where alloys of either nickel or of cobalt or of both of these metals are'desired to be produced, means analogous to the means herein set forth for the deposition of nickel and of cobalt in the desired condition and having the desired properties may be employed.
The nickel herein described differs in character from the nickel obtained by the usual metallurgical processes in that my new nickel is free from the usual poisonous contents such as sulphur, silicon, arsenic, carbon, carbides, oxygen, and other gases, and oxide containing compounds, generally present in metallurglcal nickel and rendering the same imperfect and more difficult to work. Furthermore, my new nickel is to be further differentiated from the ordinary metallur'gical nickel in that it has a finer and more even grain than such metallurgical nickel, as is shown by metallographic micro-photographs. It is also considerably purer than such metallurgical nickel, resists chemical action better and has ahigher melting point. The nickel described herein is also to be differentiated from the usual electrodeposited nickel in that it is substantially free from pores, pits and hydrogen, and is malleable and ductile to a' very high degree, unlike the usual electrodeposited nickel which is porous, contains a large hydrogen content and is brittle and unworkable A further diflerence in character between my new nickel and the ordinary metallurgical nickel is shown by the fact that the film of oxide formed by heating my new nickel in an oxidizing atmosphere is thinner, finer in texture and more adherent and flexible than the oxide coating formed by similar treatment of ordinary metallurgical nickel. Furthermore, such oxide coating in the case of my new nickel is of a different color, generally yellow to brown, while the oxide coating on the metallurgical nickel is generallyviolet or indigo in color.
It is of course, to be understood that the invention is not to be limited to the specific illustrative embodiment herein described for purposes of example onl It is also to be understood that the applicant does not wish to have the invention or the appended claims in any way limited by any particular theory of operation which he may now hold and which may be suggested by the foregoing detailed description.
What I claim is:
1. In the electrodeposition of nickelmetals, a bath comprising a salt of a nickel metal in solution, and a finely divided hydrate of a nickel metal in suspension therein.
2. In the electrodeposition of nickel, a bath comprising a salt of nickel in solution,
ltl
and a finely divided hydrate of nickel in suspension therein.
3. In the electrodeposition of nickel metals, a bath com rising, in solution, a salt of a nickel metal, and an agent adapted during electrodeposition to produce a finely divided hydrate of a nickel metal in suspension in the bath.
4. In the el-ectrodeposition of nickel, a bath comprising, in solution, a salt of nickel, and an agent adapted during electrodeposition to produce a finely divided hydrate of nickel in suspension in the bath.
5. In the electrodeposition of nickel, a bath comprising, in suspension, finely divided nickel hydrate, and, in solution, a salt of nickel, and an agent adapted during electrodeposition to produce a finely divided hydrate of nickel in suspension in the bath.
6. A method of electrodepositing nickel metals which comprises intermittently electrodepositing a nickel metal on the cathode from a bath containing, in solution, a chloride of a nickel metal an a ent adapted during deposition to provide a nely divided hydrate of a nickel metal in suspension in said bath, and boric acid, and, insuspension, a finely divided hydrate of a nickel metal, and successively bringing .the surfaces of the successive deposits into contact with a gaseous medium for a period of time sufficiently long to permit the hydrogen in the deposited surfaces to be dissipated, but
not long enough to cause the successive deposits to be separable, whereby a homogeneous, unitary nickel metal is formed.
In testimony whereof, I have signed my name to this specification this 26th day of April, 1919.
dense, deposit CHARLES P. MADSEN.
Priority Applications (2)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
US292793A US1608706A (en) | 1919-04-26 | 1919-04-26 | Electrodeposition of metals |
GB19316/19A GB142432A (en) | 1919-04-26 | 1919-08-05 | Improvements in and relating to electrodeposited metals |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
US292793A US1608706A (en) | 1919-04-26 | 1919-04-26 | Electrodeposition of metals |
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US1608706A true US1608706A (en) | 1926-11-30 |
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US292793A Expired - Lifetime US1608706A (en) | 1919-04-26 | 1919-04-26 | Electrodeposition of metals |
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US (1) | US1608706A (en) |
GB (1) | GB142432A (en) |
Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2449422A (en) * | 1944-04-15 | 1948-09-14 | Harshaw Chem Corp | Electrodeposition of nickel |
-
1919
- 1919-04-26 US US292793A patent/US1608706A/en not_active Expired - Lifetime
- 1919-08-05 GB GB19316/19A patent/GB142432A/en not_active Expired
Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2449422A (en) * | 1944-04-15 | 1948-09-14 | Harshaw Chem Corp | Electrodeposition of nickel |
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GB142432A (en) | 1920-12-05 |
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