US760852A - Manufacture of nickel carbonyl. - Google Patents

Manufacture of nickel carbonyl. Download PDF

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US760852A
US760852A US13232002A US1902132320A US760852A US 760852 A US760852 A US 760852A US 13232002 A US13232002 A US 13232002A US 1902132320 A US1902132320 A US 1902132320A US 760852 A US760852 A US 760852A
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nickel
oxid
pressure
manufacture
carbonic
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James Dewar
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    • CCHEMISTRY; METALLURGY
    • C01INORGANIC CHEMISTRY
    • C01GCOMPOUNDS CONTAINING METALS NOT COVERED BY SUBCLASSES C01D OR C01F
    • C01G1/00Methods of preparing compounds of metals not covered by subclasses C01B, C01C, C01D, or C01F, in general
    • C01G1/04Carbonyls

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  • N 0. 12,626 of 1890 is described a process for recovering nickel from'its ores by calcining the ore, so as to get into the condition of an oxid,.reduc. ing the oxid by subjecting it to the action of reducing-gases, treating with carbonic oxid the metal obtained by the reduction, and thereby producing a compound vapor mixed with the excess of carbonic oxid called in the speci fication 'nickel' carbon oxid,but now generally known as nickel carbonyl.
  • This substance can be separated as'a liquid, which on beingheated vaporizes and becomes decomposed, the carbonic oxid being liberated and pure nickel being deposited as coherent'metal.
  • the nickel carbonyl vapor at ordinary pres-- sures is very unstable, its components becoming readily dissociated with explosion on-moderate elevation of temperature, and therefore its production has hitherto been carried on at a comparatively low temperature, such as 50 centigrade.
  • the nickel obtained by reduction of the oxid I subject in a strong vessel to the action of carbonic oxid compressed to from two to one hundred atmospheres according to the'temperature, applying heat so as to raise the contents of the vessel to temperatures from 50 to 250 centigrade.
  • the nickel thus treated rapidly combines with the carbonic oxid, pro- Seriel No. 132,320; No specimens.
  • the nickel carbonyl is deposited as a liquid which can be used for production of metallic nickel in the manner de-.
  • the condensed nickel carbonyl flows into the receiver N, from which it may be drawn off by means of a cock n.
  • the excess of carbonic oxid passes onby pipe 0 to the circulating-pump P, which passes it into the carbonic oxid main H, where it again circulates as in the first operation.
  • a fresh supply of carbonic oxid is introduced by the compressor F.
  • the circu-- lation of the carbonic oxid is kept up as long as nickel carbonyl is produced.
  • the three retorts shown are for continuous working. While the nickel oxid in No. 1 is being reduced, No. 2is in use for gasifying the nickel and No. 3 is being recharged. These retorts are heated by gas-jets regulated by index-cocks. Regulating-valves are distributed throughout the circuit to control the various operations.
  • the temperature of gasification of the nickel has been taken as 100 centigrade and the pressure of fifteen atmospheres is found amply suificient; but it it is in no way to be inferred that this is the only temperature or pressure available. Thus at 180, centigrade a pressure of eighty atmospheres has been found equally ample.
  • These examples are illustrative and indicate the fact that the temperature and pressure within the scope of my invention are correlated. As the pressure is increased the temperature is correspondingly increased, the two illustrative examples being representations of the relative increase of pressure and temperature.
  • the gas containing it may be passed into a chamber heated to a temperature high enough to decompose the nickel carbonyl for obtaining metallic nickel, the temperature necessary depending on whether the pressure of the gas is maintained or allowed to fall.
  • Aprocess for the manufacture of nickel carbonyl consisting in passing carbonic oxid over heated metallic nickel under a pressure between two atmospheres and one hundred atmospheres, condensing the nickel carbonyl to separate it from the excess of carbonic oxid while the gases are still under pressure and passing the carbonic oxid again over metallic nickel, while still under pressure, substantially as described.
  • a process for the manufacture of nickel carbonyl consisting in passing carbonic oxid over metallic nickel heated to substantially 100 centigrade under a pressure of approximately fifteen atmospheres, substantially as described.
  • a process for the manufacture of nickel carbonyl consisting in passing carbonic oxid over a metallic nickel heated to substantially 100 centigrade under a pressure of approximately fifteen atmospheres, condensing the nickel carbonyl to separate it from the excess of carbonic oxid while the gases are still under pressure and passing the carbonic oxid again over metallic nickel, while still under pressure, substantially as described.

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  • Organic Chemistry (AREA)
  • Inorganic Chemistry (AREA)
  • Organic Low-Molecular-Weight Compounds And Preparation Thereof (AREA)
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Description

No. 760,852, PATENTED MAY24, 1904:.v J. DBWAR. MANUFACTURE OF NICKEL GARBONYL.
APPLICATION FILED NOV. 21. 1902.
NO MODEL.
jflveizfw? Jiilzwjewwr UNITED ST TE Iatented May 24, 1904.
PATENT OFFICE.
I'JAMES. DEWAR, OF CAMBRIDGE, ENGLAND.
' MANUFACTURE OF NICKE L CARBONYL.
'SiEQIEiGATION forming part of Letters Patent No. 760,852, dated May 24, 1904.
ApplicationfiledNovember 21, 1902.
T at whom may concern/.-
Be it known that I, J AMEs'D wAR, a citizen of England, residing at N o. l Scroop Terrace, Cambridge, in the county of Cambridge, England, have inventeda certain new and useful Improvement in the Manufacture of Nickel Carbonyl, (for .which I have applied for a patent in Great Britain, dated April 22, 1902, No. 9,300,) of which the following is a specification.
In Monds British specification, N 0. 12,626 of 1890, is described a process for recovering nickel from'its ores by calcining the ore, so as to get into the condition of an oxid,.reduc. ing the oxid by subjecting it to the action of reducing-gases, treating with carbonic oxid the metal obtained by the reduction, and thereby producing a compound vapor mixed with the excess of carbonic oxid called in the speci fication 'nickel' carbon oxid,but now generally known as nickel carbonyl. This substance can be separated as'a liquid, which on beingheated vaporizes and becomes decomposed, the carbonic oxid being liberated and pure nickel being deposited as coherent'metal. The nickel carbonyl vapor at ordinary pres-- sures is very unstable, its components becoming readily dissociated with explosion on-moderate elevation of temperature, and therefore its production has hitherto been carried on at a comparatively low temperature, such as 50 centigrade.
Now I have discovered that under considerable pressure ranging from two to one hun-- dred atmospheres the compound, either as Va por or liquid, is much more stable, and therefore higher temperatures can be employed in its production, while the rapidity of the process of manufacture is greatly increased. j I apply this discovery to the manufacture of nickel carbonyl, from which metallic nickel may be produced in the following manner.
The nickel obtained by reduction of the oxid I subject in a strong vessel to the action of carbonic oxid compressed to from two to one hundred atmospheres according to the'temperature, applying heat so as to raise the contents of the vessel to temperatures from 50 to 250 centigrade. The nickel thus treated rapidly combines with the carbonic oxid, pro- Seriel No. 132,320; No specimens.)
with the excess of carbonic oxid in which. it
. ducing vapor of nickel carbonyl. I This vapor, 7
is diffused whilestill'under pressure,onbeing passed through tubes at.-a higher tempera.-
.ture becomes dissociated, depositing metallic nickel, while the separated and diluent carbonic oxid can be returned to act on fresh charges of spongy nickel.
If the vapor along with the excess'of carbonic oxid in which it is diffused while still under pressure be allowed to pass through a cooled condenser, the nickel carbonyl is deposited as a liquid which can be used for production of metallic nickel in the manner de-.
scribed in the specification above referred to or for other purposes, while the carbonic oxid still under pressurecan be returned to act on fresh charges of spongy nickel. x
The accompanying drawing showsdiagrammatically a plant for the manufacture of nickel carbonyl according to my invention.-
' By means of a compressor. 13 water-gas or. any other suitable gas containing hydrogen.
is passed at any desired pressure into the bot-; tom of a retort C, set in a furnace C and previously charged with nickel oxid which is kept at a temperature of about 300 centigrade.- The hydrogen of thewater-gas or other gas used reduces the nickel oxid, and
the Vapor of water formed and the excess of gas used passout of the top of the retort by a pipe. (Not shown in the drawing.) The reduced nickel oxid in the retort O is now cooled to a temperature of about 100 centigrade. Carbonic oxid prepared in any convenient way and compressed to about fifteen atmospheres by the compressor F is circulated through the retort, passing in from the carbonic-oxid main H and out at the pipe D, through. the regulating-Valve 1 into the nickelcarbonyl main J, which. conveys it into the dust-chamber K. From here it enters the cooler L, passing through a coil immersed in Water into the condenser M, which vmay be cooled in any convenient manner. The condensed nickel carbonyl flows into the receiver N, from which it may be drawn off by means of a cock n. The excess of carbonic oxid passes onby pipe 0 to the circulating-pump P, which passes it into the carbonic oxid main H, where it again circulates as in the first operation. As the carbonic oxid combines with the nickel and the pressure-is thus reduced, a fresh supply of carbonic oxid is introduced by the compressor F. The circu-- lation of the carbonic oxid is kept up as long as nickel carbonyl is produced. When this is the case, the inlet and outlet circulatingvalves I and S T on the retort are closed, and the gas in the retort is pumped out by means of the compressor F, after which the retort is cleareol by removing the cover and is recharged for a second operation.
The three retorts shown are for continuous working. While the nickel oxid in No. 1 is being reduced, No. 2is in use for gasifying the nickel and No. 3 is being recharged. These retorts are heated by gas-jets regulated by index-cocks. Regulating-valves are distributed throughout the circuit to control the various operations.
For the purpose of description the temperature of gasification of the nickel has been taken as 100 centigrade and the pressure of fifteen atmospheres is found amply suificient; but it it is in no way to be inferred that this is the only temperature or pressure available. Thus at 180, centigrade a pressure of eighty atmospheres has been found equally ample. These examples are illustrative and indicate the fact that the temperature and pressure within the scope of my invention are correlated. As the pressure is increased the temperature is correspondingly increased, the two illustrative examples being representations of the relative increase of pressure and temperature.
It is obvious that instead of condensing the nickel carbonyl the gas containing it may be passed into a chamber heated to a temperature high enough to decompose the nickel carbonyl for obtaining metallic nickel, the temperature necessary depending on whether the pressure of the gas is maintained or allowed to fall.
According to my invention an acceleration of the reaction and a more rapid output is obtained, and this useful result is one that is increased gradually as the pressure is raised from two atmospheres to one hundred atmospheres, because as the pressure is raised the temperature can also be raised.
Having thus described the nature of this invention and the best means I know of carrying the same into practical elfect, I claim 1. A process for the manufacture of nickel carbonyl consisting in passing carbonic oxid over heated metallic nickel under a pressure between two atmospheres and one hundred atmospheres, substantially as described.
2. Aprocess for the manufacture of nickel carbonyl, consisting in passing carbonic oxid over heated metallic nickel under a pressure between two atmospheres and one hundred atmospheres, condensing the nickel carbonyl to separate it from the excess of carbonic oxid while the gases are still under pressure and passing the carbonic oxid again over metallic nickel, while still under pressure, substantially as described.
3. A process for the manufacture of nickel carbonyl, consisting in passing carbonic oxid over metallic nickel heated to substantially 100 centigrade under a pressure of approximately fifteen atmospheres, substantially as described.
4.. A process for the manufacture of nickel carbonyl, consisting in passing carbonic oxid over a metallic nickel heated to substantially 100 centigrade under a pressure of approximately fifteen atmospheres, condensing the nickel carbonyl to separate it from the excess of carbonic oxid while the gases are still under pressure and passing the carbonic oxid again over metallic nickel, while still under pressure, substantially as described.
In testimony whereof I have hereunto set my hand in presence of two subscribing witnesses.
JAMES DE\VAR.
Witnesses:
, OLIVER INNACE,
GERALD L. SMITH.
US13232002A 1902-11-21 1902-11-21 Manufacture of nickel carbonyl. Expired - Lifetime US760852A (en)

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Cited By (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2731361A (en) * 1952-12-09 1956-01-17 Ohio Commw Eng Co Catalyzed deposition of metals from the gaseous state
US3076693A (en) * 1958-04-10 1963-02-05 Int Nickel Co Method for producing nickel carbonyl
US4250157A (en) * 1980-04-11 1981-02-10 Pentanyl Technologies, Inc. Method and apparatus for enriching the iron carbonyl content of a recycle gas stream
US4801374A (en) * 1986-06-27 1989-01-31 Maschinenfabrik Heid Aktiengesellschaft Apparatus for the treatment of seed materials

Cited By (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2731361A (en) * 1952-12-09 1956-01-17 Ohio Commw Eng Co Catalyzed deposition of metals from the gaseous state
US3076693A (en) * 1958-04-10 1963-02-05 Int Nickel Co Method for producing nickel carbonyl
US4250157A (en) * 1980-04-11 1981-02-10 Pentanyl Technologies, Inc. Method and apparatus for enriching the iron carbonyl content of a recycle gas stream
US4801374A (en) * 1986-06-27 1989-01-31 Maschinenfabrik Heid Aktiengesellschaft Apparatus for the treatment of seed materials

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