US2744004A - Method of lowering the carbon content of high carbon ferrochromium - Google Patents
Method of lowering the carbon content of high carbon ferrochromium Download PDFInfo
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- US2744004A US2744004A US333595A US33359553A US2744004A US 2744004 A US2744004 A US 2744004A US 333595 A US333595 A US 333595A US 33359553 A US33359553 A US 33359553A US 2744004 A US2744004 A US 2744004A
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- carbon
- ferrochromium
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- C—CHEMISTRY; METALLURGY
- C21—METALLURGY OF IRON
- C21D—MODIFYING THE PHYSICAL STRUCTURE OF FERROUS METALS; GENERAL DEVICES FOR HEAT TREATMENT OF FERROUS OR NON-FERROUS METALS OR ALLOYS; MAKING METAL MALLEABLE, e.g. BY DECARBURISATION OR TEMPERING
- C21D3/00—Diffusion processes for extraction of non-metals; Furnaces therefor
- C21D3/02—Extraction of non-metals
- C21D3/04—Decarburising
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B22—CASTING; POWDER METALLURGY
- B22F—WORKING METALLIC POWDER; MANUFACTURE OF ARTICLES FROM METALLIC POWDER; MAKING METALLIC POWDER; APPARATUS OR DEVICES SPECIALLY ADAPTED FOR METALLIC POWDER
- B22F1/00—Metallic powder; Treatment of metallic powder, e.g. to facilitate working or to improve properties
- B22F1/14—Treatment of metallic powder
- B22F1/145—Chemical treatment, e.g. passivation or decarburisation
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- C—CHEMISTRY; METALLURGY
- C22—METALLURGY; FERROUS OR NON-FERROUS ALLOYS; TREATMENT OF ALLOYS OR NON-FERROUS METALS
- C22C—ALLOYS
- C22C33/00—Making ferrous alloys
- C22C33/02—Making ferrous alloys by powder metallurgy
- C22C33/0207—Using a mixture of prealloyed powders or a master alloy
Definitions
- This invention relates to a method of lowering the. carbon content of high carbon ferrochromium to produce medium carbon and low carbon ferrochromiums.
- An object of the invention is to provide a process for reducin the carbon analysis of high carbon ferrochro- Ilium without materially contaminating the product with heigmaterials.
- Another object is to provide a process for reducing the carbon content of high carbon ferroch-romium in a and economical manner.
- Another object of the invention is to provide a method of lowering the carbon content of high carbon ferrochromium wherein no lime or similar materials are used for the purpose of keeping the charge in an open condition.
- Another object of the invention is to utilize gaseous reagents in the treatment of high carbon ferrochromium for reduction of its carbon content.
- the reduction step of the process preferably is conducted in a fluidized bed utilizing a reducing gas as the fluidizing medium.
- a preferred oxidizing gas for employment in the oxidation step of the process is air, but substantially pure oxygen or carbon dioxide gas may also be used as well as other oxidizing gases and mixtures of such gases.
- Hydrogen is a typical and preferred gas for effecting reduction in the final stage of' the process.
- reducing agents such as carbon monoxide, water gas, methane, or mixtures thereof may be employed advnmageously.
- high carbon ferrochromium is considered to contain carbon in amounts ranging from 4% to 8% in addition to its principal. con stituents, chromium and iron and its minor components, silicon, aluminum, calcium, magnesium and the like.
- Medium carbon ferrochromium contains. from. 1. to whon, and. low carbon fcrrochromium contains less than 1% carbon.
- carbon ferrochromium contains less than. 0..lO. carbon.
- high carbon ferrochromium containing carbon in the amount of 7 /z%, for example is ground in a suitable milling apparatus to provide fine ferrochromiurn powder.
- the fineness of the comminuted high carbon ferrochromium is such that about 60% of the powder will pass through a 200 mesh screen, for example.
- the finely ground ferrochromium is introduced into a conventional fluid bed roaster or reactor having the usual heating or cooling devices and operated either continuously or batch-wise, in ways well known in the art. Air, or other oxidizing gas, is blown upwardly through the bed of ferrochromium in the reactor, and heating conditions are adjusted to provide the desired temperature in the fluidized bed.
- the oxidizing reaction should be carried out at a ternperature between 900 C. and 1400 C.
- the oxidizing reaction is allowed to proceed for a suflicient period of time to lower the carbon content to the preselected
- the carbon content may be reduced to about 5% with a concomitant oxidation of a substantial, though low amount of the metal constituents of the ferrochromium.
- the metal of the ferrochrornium is largely converted to metallic oxides.
- the partially oxidized ferroehromium which then has the desired carbon content, is reduced with a gaseous reducing agent to return the metallic oxides to elemental metal.
- the reduction step is advantageously performed in a fluid bed reactor similar to that in which the oxidation step is carried out.
- the gaseous reduction step may be performed in the same reactor.
- Hydrogen may be used as a fluidizing and reducing gas. Temperature conditions in the bed. are maintained in the range 1000 C. to 1400 C. or somewhat higher and reduction is allowed to proceed for a time sutficient to substantially convert the metallic oxides to metal.
- the reduction step preferably is carried out in a finid bed reactor, it may be performed in any suitable apparatus wherein the partially oxidized ferrochromi'um is subjected to a reducing atmosphere at elevated temperature.
- High carbon ferrochromium containing 50.9% chro- 7.3% carbon is dry-ground in. a ball mill to provide a comminuted powdered ferrochromium having the following typical screen analysis:
- a charge of the finely ground ferrochromium is placed in a fluid bed reactor equipped with a silicon carbide reaction tube having a perforated bottom for admission of fluidizing gas. Atmospheric air is admitted to the reaction tube through the perforated bottom at a rate sufficient to maintain the bed of ferrochromium particles in a fluidized condition.
- the temperature of the bed is raised to a suitable reaction temperature in the range of 900 C. to 1400 C.
- Test samples are taken from the fluidized bed at intervals and analysed for carbon. When the carbon is reduced to the desired value, the reactor is shut down and prepared for the reduction operation.
- the following table shows inter alia the manner in which the carbon analysis of the ferrochromium is affected at temperatures ranging from 700 C. to 1350 C.
- a method of lowering the carbon content of high carbon ferrochromium which comprises comminuting high carbon ferrochromium, establishing a fluidized bed of said high carbon ferrochromium by blowing upwardly through a body thereof a stream of oxidizing gas, maintaining said fluidized bed at a temperature of from 900 C. to 1400" C. for a time sufficient to oxidize a substantial portion of the carbon and metal of said ferrochromium and to remove said carbon from said ferrochromium as an oxide of carbon, and thereafter treating said partially oxidized ferrochromium at an elevated tempera ture in a strongly reducing atmosphere of reducing gas for a time sufficient to reduce a substantial portion of the metal oxide content of the ferrochromium to metal.
- a method of lowering the carbon content of high carbon ferrochromium which comprises comminuting high carbon ferrochromium, establishing a fluidized bed of said high carbon ferrochromium by blowing upwardly through a body thereof a stream of air, maintaining said fluidized bed at a temperature of from 900 C. to 1400 C.
- the partially oxidized material prepared at 1350 C. in 5.25 hours and analyzing 42.74% Cr, 3.3% C, and 3.97% Si is heated in the fluid bed reactor under fluidizing conditions using hydrogen as the fiuidizing and reducing gas at a temperature of 1300 C. for 5 hours.
- the reactor is shut down and cooled and the reduced product is removed.
- the reduced product has the fol lowing chemical analysis:
- a method of lowering the carbon content of high carbon ferrochromium which comprises comminuting high carbon ferrochromium, establishing a fluidized bed of said high carbon ferrochromium by blowing upwardly through a body thereof a stream of air, maintaining. said fluidized bed at a temperature of from 900 C. to 1400"- C. for a time suflicient to oxidize a substantial portion;
- a method of lowering the carbon content of high carbon ferrochromium which comprises comminuting high carbon ferrochromium, establishing a fluidized bed of said high carbon ferrochromium by blowing upwardly through a body thereof a stream of oxidizing gas, maintaining said fluidized bed at a temperature of from 900 C. to 1400 C. for a time sufiicient to oxidize a substantial portion of the carbon and metal of said ferrochromium and to remove said carbon from said ferrochromium as an oxide of carbon, and thereafter establishing a fluidized bed of said partially oxidized ferrochromium by blowing upwardly through a body thereof a stream of strongly reducing gas, maintaining said fluidind bed at. an elevated temperature for a time suflicient to reduce a substantial portion of the metal oxide content of the ferrochromium to metal.
- a method of lowering the carbon content of high carbon ferrochromium which comprises comminuting high carbon ferrochromium, establishing a fluidized bed of said high carbon ferrochromium by blowing upwardly through a body thereof a stream of air, maintaining said fluidized bed at a temperature of from 900 C. to 1400 C.
- a method of lowering the carbon content of high carbon ferrochromium which comprises oomminuting high carbon ferrochromium, establishing a fluidized bed of said high carbon ferrochromium by blowing upwardly through a body thereof a stream of oxidizing gas, maintaining said fluidized bed at a temperature of from 900 C. to 1400 C. for a time sufficient to oxidize a substantial portion of the carbon and metal of said ferrochromium and to remove said carbon from said ferrochromium as an oxide of carbon, and thereafter establishing a fluidized bed of said partially oxidized ferrochromium by blowing upwardly through a body thereof a stream of strongly reducing gas, maintaining said fluidized bed at a temperature of from 1000 C. to 1400 C. for a time suflicient to reduce a substantial portion of the metal oxide content of the ferrochromium to metal.
- a method of lowering the carbon content of high carbon ferrochromium which comprises comminuting high carbon ferrochromium, establishing a fluidized bed of said high carbon ferrochromium by blowing upwardly through a body thereof a stream of air, maintaining said fluidized bed at a temperature of from 900 C. to 1400 C. for a time sutficient to oxidize a substantial portion of the carbon and metal of said ferrochromium and to remove said carbon from said ferrochromium as an oxide of carbon, and thereafter establishing a fluidized bed of said partially oxidized ferrochromium by blowing upwardly through a body thereof a stream of hydrogen, maintaining said fluidized bed at a temperature of from 1000 C. to 1400" C. for a time sufficient to reduce a substantial portion of the metal oxide content of the ferrochromium to metal.
Description
United States Patent m0!) OF LOWERING THE CARBON CONTENT OF HIGH CARBON FERROCHROMIUM Alan R. Fraser, Sault Ste. Marie, Ontario, Canada, as-
Igor to Chromium Mining & smelting Corporation, Lhlted, Sault Ste. Marie, Ontario, Canada, a corporaflmd Canada No Drawing. Application January 27, 1953,
Serial No. 333,595 I 8 Claims. (CI. 75-26) This invention relates to a method of lowering the. carbon content of high carbon ferrochromium to produce medium carbon and low carbon ferrochromiums.
An object of the invention is to provide a process for reducin the carbon analysis of high carbon ferrochro- Ilium without materially contaminating the product with heigmaterials.
Another object is to provide a process for reducing the carbon content of high carbon ferroch-romium in a and economical manner. 7
Another object of the invention is to provide a method of lowering the carbon content of high carbon ferrochromium wherein no lime or similar materials are used for the purpose of keeping the charge in an open condition.
Another object of the invention is to utilize gaseous reagents in the treatment of high carbon ferrochromium for reduction of its carbon content.
The foregoing and other objects of the invention as may appear hereinafter are achieved in a method of lowering the carbon content of high carbon ferrochromium which includes comminuting high carbon ferroehromium, establishing a fluidized bed of the comrninuted' high carbon ferrochromium, by blowing upwardly through the bed a stream of oxidizing gas, establishing and maintaining in the fluidized bed a temperature of from 900 C. 1400" C. for a time sufiicient to oxidize a substantial portion of the carbon and metal of the ferrochromium and to remove the carbon from the ferrochromium as an oxide of carbon, and thereafter treating'the partially oxidized fierrochromium at an elevated temperature in an atmosphere of reducing gas for a time sufficient to reduce a.v substantial portion of the metal oxide content of the ferrochromium to elemental metal.
The reduction step of the process preferably is conducted in a fluidized bed utilizing a reducing gas as the fluidizing medium.
A preferred oxidizing gas for employment in the oxidation step of the process is air, but substantially pure oxygen or carbon dioxide gas may also be used as well as other oxidizing gases and mixtures of such gases.
Hydrogen is a typical and preferred gas for effecting reduction in the final stage of' the process. However, other reducing agents such. as carbon monoxide, water gas, methane, or mixtures thereof may be employed advnmageously.
For purposes of the present specification, high carbon ferrochromium is considered to contain carbon in amounts ranging from 4% to 8% in addition to its principal. con stituents, chromium and iron and its minor components, silicon, aluminum, calcium, magnesium and the like. Medium carbon ferrochromium contains. from. 1. to whon, and. low carbon fcrrochromium contains less than 1% carbon. carbon ferrochromium contains less than. 0..lO. carbon.
A particularly desirable and. valuable low 1 value.
2,744,004 Patented May 1, 1956 The ferrochromiums defined in the immediately preceding paragraph are used as alloying materials in the production of low chromium steels and stainless steels. Since in making such steels the carbon content must be lowered to and kept within a specified and usually low range of values, it is possible to use the higher carbon containing ferrochromiums for the production only of steels having relatively low chromium content. Where the chromium content of the steel is high, as in 18/8 chromium/nickel stainless steel, it is necessary to use ferrochromium having a very low carbon analysis as the alloying metal. Accordingly the present invention is utilized to provide ferrochromiums of reduced carbon content for use in making. chromium steels having relatively high content of chromium.
In accordance with the invention, high carbon ferrochromium containing carbon in the amount of 7 /z%, for example, is ground in a suitable milling apparatus to provide fine ferrochromiurn powder. The fineness of the comminuted high carbon ferrochromium is such that about 60% of the powder will pass through a 200 mesh screen, for example.
The finely ground ferrochromium is introduced into a conventional fluid bed roaster or reactor having the usual heating or cooling devices and operated either continuously or batch-wise, in ways well known in the art. Air, or other oxidizing gas, is blown upwardly through the bed of ferrochromium in the reactor, and heating conditions are adjusted to provide the desired temperature in the fluidized bed. In accordance with the invention, the oxidizing reaction should be carried out at a ternperature between 900 C. and 1400 C. The oxidizing reaction is allowed to proceed for a suflicient period of time to lower the carbon content to the preselected The carbon content may be reduced to about 5% with a concomitant oxidation of a substantial, though low amount of the metal constituents of the ferrochromium. to form a product in which some of the metallics exist as oxides. If the oxidation reaction is allowed to proceed to the point where carbon is reduced to 2%, a larger portion of the metal of the ferrochromium is oxidized. Where extremely low carbon content, for example less than 1% carbon is achieved in the oxidation step, the metal of the ferrochrornium is largely converted to metallic oxides.
Following the oxidation step, the partially oxidized ferroehromium, which then has the desired carbon content, is reduced with a gaseous reducing agent to return the metallic oxides to elemental metal. The reduction step is advantageously performed in a fluid bed reactor similar to that in which the oxidation step is carried out. Alternatively the gaseous reduction step may be performed in the same reactor. Hydrogen may be used as a fluidizing and reducing gas. Temperature conditions in the bed. are maintained in the range 1000 C. to 1400 C. or somewhat higher and reduction is allowed to proceed for a time sutficient to substantially convert the metallic oxides to metal.
Although the reduction step preferably is carried out in a finid bed reactor, it may be performed in any suitable apparatus wherein the partially oxidized ferrochromi'um is subjected to a reducing atmosphere at elevated temperature.
The invention will be described more particularly hereinafter with reference to the production of medium carbon ierrochromium from. high carbon ferrochromium.
High carbon ferrochromium containing 50.9% chro- 7.3% carbon is dry-ground in. a ball mill to provide a comminuted powdered ferrochromium having the following typical screen analysis:
A charge of the finely ground ferrochromium is placed in a fluid bed reactor equipped with a silicon carbide reaction tube having a perforated bottom for admission of fluidizing gas. Atmospheric air is admitted to the reaction tube through the perforated bottom at a rate sufficient to maintain the bed of ferrochromium particles in a fluidized condition. The temperature of the bed is raised to a suitable reaction temperature in the range of 900 C. to 1400 C. Test samples are taken from the fluidized bed at intervals and analysed for carbon. When the carbon is reduced to the desired value, the reactor is shut down and prepared for the reduction operation.
The following table shows inter alia the manner in which the carbon analysis of the ferrochromium is affected at temperatures ranging from 700 C. to 1350 C.
tion of its carbon content in accordance with the invention.
I claim:
1. A method of lowering the carbon content of high carbon ferrochromium which comprises comminuting high carbon ferrochromium, establishing a fluidized bed of said high carbon ferrochromium by blowing upwardly through a body thereof a stream of oxidizing gas, maintaining said fluidized bed at a temperature of from 900 C. to 1400" C. for a time sufficient to oxidize a substantial portion of the carbon and metal of said ferrochromium and to remove said carbon from said ferrochromium as an oxide of carbon, and thereafter treating said partially oxidized ferrochromium at an elevated tempera ture in a strongly reducing atmosphere of reducing gas for a time sufficient to reduce a substantial portion of the metal oxide content of the ferrochromium to metal.
2. A method of lowering the carbon content of high carbon ferrochromium which comprises comminuting high carbon ferrochromium, establishing a fluidized bed of said high carbon ferrochromium by blowing upwardly through a body thereof a stream of air, maintaining said fluidized bed at a temperature of from 900 C. to 1400 C. for a time suflicient to oxidize a substantial portion of the carbon and metal of said ferrochromium and to remove said carbon from said ferrochromium as an oxide of carbon, and thereafter treating said partially oxidized ferrochromium at an elevated temperature in a strongly for tunes up to hours: reducing atmosphere of hydrogen for a time sutficient Table II Stack Gas Perce t P nt P t Assay n erce ercen Sample Treatment Cr C Si Percent Percent (1) 700 C. roast-material At 700 C. for 0.66 hrs 51. 90 7.1 5. 57 0, 2 20, 3 (2) 700 C. roast-material At 700 C. for 2.5 hrs 51. 84 0. 9 5. 59 0. 5 20. 5 (3) 700 0. roast-material" At 700 C. for 3.5 hrs 51. 84 6.9 5. 62 0.0 21. 0 (1) 1.200 C. roast-material. At 1,200 C. for 0.66 hrs. 40. 60 5. 4 5. 60 l. 0 19. 5 (2) 1,200 C. roast-material. At l,200 C. for 1.66 hrs 49. 36 5.1 5. 58 1. 0 18.0 (3) 1,200 O. roast-matcriaL At 1,200 C. for 3.16 hrs 48. 21 4. 5 5.24 2.0 16. 5 (4) 1,200 C. roast-material. At 1,200 O. for 4.66 hrs. 47. 36 4.2 5. 1.0 17. 0 (1) 1,350" O. roast-materia-L At 1,350 G for 1.08 hrs.- 45. 40 3. 7 5. 29 1.0 2 1,350 C. roast-material. At 1,350 C for 2.5 hrs 44. 94 3.8 4.97 1. 5 1 5 (3) 1,350 C. roast-material... At 1,350 G. for 4.5 hrs 43. 37 3. 4 4. 84 0. 5 18. 5 (4) 1,350 C. roast-material At 1,350 C. for 5.25 hrs 42. 74 3. 3 8. 97 0. 5 18. 5
From a consideration of Table II it is seen that no appreciable carbon oxidation occurs at 700 C. in 3 /2 hours. At 1200 C. the carbon is reduced to 5.4% in the first 0.66 hour of operation and is further reduced to 4.2% after 4.66 hours. At 1350" C. the carbon content is reduced to 3.7% in the first 1.08 hours and is further reduced to 3.3% in 5.25 hours.
The partially oxidized material prepared at 1350 C. in 5.25 hours and analyzing 42.74% Cr, 3.3% C, and 3.97% Si is heated in the fluid bed reactor under fluidizing conditions using hydrogen as the fiuidizing and reducing gas at a temperature of 1300 C. for 5 hours. The reactor is shut down and cooled and the reduced product is removed. The reduced product has the fol lowing chemical analysis:
Per cent 49.04 C 3.79- Si 4.55
regardless of carbon content that is amenable to reduc-- portion of the carbon and metal of said ferrochromium and to remove said carbon from said ferrochrcmium as an oxide of carbon, and thereafter treating said partially oxidized ferrochromium at a temperature of from 1000" C. to 1400 C. in a strongly reducing atmosphere of reducing gas for a time sufficient to reduce a substantial portion of the metal oxide content of the fcrrochromium to metal.
4. A method of lowering the carbon content of high carbon ferrochromium which comprises comminuting high carbon ferrochromium, establishing a fluidized bed of said high carbon ferrochromium by blowing upwardly through a body thereof a stream of air, maintaining. said fluidized bed at a temperature of from 900 C. to 1400"- C. for a time suflicient to oxidize a substantial portion;
of the carbon and metal of said ferrochromiumand to remove said carbon from said ferrochromium as an oxide.
of'ca'rbon, and thereafter treating said partially oxidized ferrochromium at a temperature of from 1000 C. to 1400 C. m a strongly reducing atmosphere of hydrogen for a time sufficient to reduce a substantial portion of the metal oxide content of the ferrochromium to metal.
5. A method of lowering the carbon content of high carbon ferrochromium which comprises comminuting high carbon ferrochromium, establishing a fluidized bed of said high carbon ferrochromium by blowing upwardly through a body thereof a stream of oxidizing gas, maintaining said fluidized bed at a temperature of from 900 C. to 1400 C. for a time sufiicient to oxidize a substantial portion of the carbon and metal of said ferrochromium and to remove said carbon from said ferrochromium as an oxide of carbon, and thereafter establishing a fluidized bed of said partially oxidized ferrochromium by blowing upwardly through a body thereof a stream of strongly reducing gas, maintaining said fluidind bed at. an elevated temperature for a time suflicient to reduce a substantial portion of the metal oxide content of the ferrochromium to metal.
6. A method of lowering the carbon content of high carbon ferrochromium which comprises comminuting high carbon ferrochromium, establishing a fluidized bed of said high carbon ferrochromium by blowing upwardly through a body thereof a stream of air, maintaining said fluidized bed at a temperature of from 900 C. to 1400 C. for a time suflicient to oxidize a substantial portion of the carbon and metal of said ferrochromium and to remove said carbon from said ferrochromium as an oxide of carbon, and thereafter establishing a fluidized bed of said partially oxidized ferrochromium by blowing upwardly through a body thereof a stream of hydrogen, maintaining said fluidized bed at an elevated temperature for a time sufficient to reduce a substantial portion of the metal oxide content of the ferrochromium to metal.
7. A method of lowering the carbon content of high carbon ferrochromium which comprises oomminuting high carbon ferrochromium, establishing a fluidized bed of said high carbon ferrochromium by blowing upwardly through a body thereof a stream of oxidizing gas, maintaining said fluidized bed at a temperature of from 900 C. to 1400 C. for a time sufficient to oxidize a substantial portion of the carbon and metal of said ferrochromium and to remove said carbon from said ferrochromium as an oxide of carbon, and thereafter establishing a fluidized bed of said partially oxidized ferrochromium by blowing upwardly through a body thereof a stream of strongly reducing gas, maintaining said fluidized bed at a temperature of from 1000 C. to 1400 C. for a time suflicient to reduce a substantial portion of the metal oxide content of the ferrochromium to metal.
8. A method of lowering the carbon content of high carbon ferrochromium which comprises comminuting high carbon ferrochromium, establishing a fluidized bed of said high carbon ferrochromium by blowing upwardly through a body thereof a stream of air, maintaining said fluidized bed at a temperature of from 900 C. to 1400 C. for a time sutficient to oxidize a substantial portion of the carbon and metal of said ferrochromium and to remove said carbon from said ferrochromium as an oxide of carbon, and thereafter establishing a fluidized bed of said partially oxidized ferrochromium by blowing upwardly through a body thereof a stream of hydrogen, maintaining said fluidized bed at a temperature of from 1000 C. to 1400" C. for a time sufficient to reduce a substantial portion of the metal oxide content of the ferrochromium to metal.
References Cited in the file of this patent UNITED STATES PATENTS 1,969,264 Grant Aug. 7, 1934 2,170,158 Rennerfelt Aug. 22, 1939 FOREIGN PATENTS 539,461 Great Britain Sept. 11, 1941
Claims (1)
1. A METHOD OF LOWERING THE CARBON CONTENT OF HIGH CARBON FERROCHROMIUM WHICH COMPRISES COMMINUTING HIGH CARBON FERROCHROMIUM, ESTABLISHING A FLUIDIZED BED OF SAID HIGH CARBON FERROCHROMIUM BY BLOWING UPWARDLY THROUGH A BODY THEREOF A STREAM OF OXIDIZING GAS, MAINTAINING SAID FLUIDIZED BED AT A TEMPERATURE OF FROM 900* C. TO 1400* C. FOR A TIME SUFFICIENT TO OXIDIZED A SUBSTANTIAL PORTION OF THE CARBON AND METAL OF SAID FERROCHROMIUM AND TO REMOVE SAID CARBON FROM SAID FERROCHROMIUM AS AN OXIDE CARBON AND THEREAFTER TREATING SAID PARTIALLY OXIDIZED FERROCHROMIUM AT AN ELEVATED TEMPERATURE IN A STRONGLY REDUCING ATMOSPHERE OF REDUCING GAS FOR A TIME SUFFICIENT TO REDUCE A SUBSTANTIAL PORTION OF THE METAL OXIDE CONTENT OF THE FERROCHROMIUM TO METAL.
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Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US3222212A (en) * | 1962-11-29 | 1965-12-07 | Alloy Surfaces Co Inc | Process for chromizing |
Citations (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US1969264A (en) * | 1931-04-07 | 1934-08-07 | Wheadon M Grant | Method of reducing metals from oxidized materials |
US2170158A (en) * | 1935-11-04 | 1939-08-22 | Rennerfelt Ivar | Method of decarbonizing a carbon holding metal, for instance pig iron |
GB539461A (en) * | 1939-03-11 | 1941-09-11 | Ivar Rennerfelt | Improvements in or relating to the production of low carbon alloys |
-
1953
- 1953-01-27 US US333595A patent/US2744004A/en not_active Expired - Lifetime
Patent Citations (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US1969264A (en) * | 1931-04-07 | 1934-08-07 | Wheadon M Grant | Method of reducing metals from oxidized materials |
US2170158A (en) * | 1935-11-04 | 1939-08-22 | Rennerfelt Ivar | Method of decarbonizing a carbon holding metal, for instance pig iron |
GB539461A (en) * | 1939-03-11 | 1941-09-11 | Ivar Rennerfelt | Improvements in or relating to the production of low carbon alloys |
Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US3222212A (en) * | 1962-11-29 | 1965-12-07 | Alloy Surfaces Co Inc | Process for chromizing |
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