US1711603A - Process for production of diffused layers on metals - Google Patents

Process for production of diffused layers on metals Download PDF

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US1711603A
US1711603A US230172A US23017227A US1711603A US 1711603 A US1711603 A US 1711603A US 230172 A US230172 A US 230172A US 23017227 A US23017227 A US 23017227A US 1711603 A US1711603 A US 1711603A
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aluminium
production
powder
metals
diffused layers
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US230172A
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Lay Emil
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    • CCHEMISTRY; METALLURGY
    • C23COATING METALLIC MATERIAL; COATING MATERIAL WITH METALLIC MATERIAL; CHEMICAL SURFACE TREATMENT; DIFFUSION TREATMENT OF METALLIC MATERIAL; COATING BY VACUUM EVAPORATION, BY SPUTTERING, BY ION IMPLANTATION OR BY CHEMICAL VAPOUR DEPOSITION, IN GENERAL; INHIBITING CORROSION OF METALLIC MATERIAL OR INCRUSTATION IN GENERAL
    • C23CCOATING METALLIC MATERIAL; COATING MATERIAL WITH METALLIC MATERIAL; SURFACE TREATMENT OF METALLIC MATERIAL BY DIFFUSION INTO THE SURFACE, BY CHEMICAL CONVERSION OR SUBSTITUTION; COATING BY VACUUM EVAPORATION, BY SPUTTERING, BY ION IMPLANTATION OR BY CHEMICAL VAPOUR DEPOSITION, IN GENERAL
    • C23C10/00Solid state diffusion of only metal elements or silicon into metallic material surfaces
    • C23C10/28Solid state diffusion of only metal elements or silicon into metallic material surfaces using solids, e.g. powders, pastes
    • C23C10/34Embedding in a powder mixture, i.e. pack cementation
    • C23C10/36Embedding in a powder mixture, i.e. pack cementation only one element being diffused
    • C23C10/48Aluminising

Definitions

  • This invention relates to a process for the production of diffused layers on metals.
  • diffused fire-and corro- 5 sionresistant layers of aluminium upon metals such as iron, copper. and the like are, as is well known, produced by embeddingthe piece to be improved in a powder of aluminium or aluminium alloys and submitting same to a treatment similar to case-hardening, at temperatures lying between 700 and 1200 G., the preferred temperature being about 1100 C.
  • Ammonium chloride and inert substances such as sand, clay and the like are frequently also admixed with the hardening powder.
  • Useful diffused layers canthus be obtained by means of the hitherto known processes.
  • the present invention relates 'to afurther development of this process. Ithas been found that the qualityof the protective layer produced can be considerably improved if the metallic aluminium content of the hardening powder is ke t within certain definite limits. These limits lie between 15 and of metallicaluminium. The most favourable content generally lies in the vicinity of 20%. Alterations of and deviations from this optimum can be caused by, the temperature 30 0 treatment, the thickness of the protective layerproduced and particular qualities demanded therefrom, the composition and quality of the material to be improved and the like. If aluminium alloy powders are employed the aforesaid values can be adjusted to correspond to the aluminium content of the alloy in such a manner that the amount of the alloy is calculated on its aluminium content.
  • the hardening powders used' according to 40 the invention must obviously exhibit as uniform a dispersion of the aluminium as possible, since the aluminium concentration'would be altered by irregularities in the distribution of the-aluminium.-
  • the (powders are preferablyp'roduced by first ad ing the aluminium in small amounts up to 8% to the inert base mass consisting of clay, alumina and the like. This mixture is then preferably ignited in an inert atmosphere (in order to reduce waste by the aluminium burning) and after renewed" addition of aluminium within the same limits, it is submitted to the same treatment, these operations being continued until the desired aluminium content is obtained.
  • This method of operation has proved especially advantageous owing to the fact that when larger amounts of aluminium than those above mentioned are added to the inert material it may occur that the individual aluminium particles. agglomerate and thus render it impossible to produce a hardening powder of uniform distribution.
  • the aluminium need not be added in a very finely subdivided form but it is sufficient if it is employed in the form of chi s, such as are obtainedin works.
  • the aluminium shows a marked tendency to diffuse. It disseminates very finely and uniformly in the base mass.
  • aluminium In order to obtain a hardening powder containing about 20% aluminium, starting from pure alumina, the aluminium is added in threev stages; heating to the aforesaid temperature being effected at each stage. It is preferable to employ such base masses as already contain. a certain amount of aluminium. Aluminium scrap obtained in aluminium foundries, contain aluminium in a sufliciently fine form and in amounts of 10 to 15%. If these are ground and worked up so as to separate the coarser particles, a starting ma terial which is very suitable for the production of hardening powders can be obtained.
  • the powder can always be employed over again. It'is only necessary to make up the metallic aluminium lost by the powder during the diffusion treatment, by the addition of aluminium or aluminium alloys. In the case of relatively high losses of aluminium (above 8%) this is offected inthe above-described manner. If the lossis less, it is suflicient merely to admix a corresponding amount of aluminium with the powder, as uniformly as possible.
  • the process of the invention has the advantage that the protective layer upon the.
  • the lower limit of the metallic aluminium content the hardening powder may be advantageously diminished to approximately 8%. In consequence'thereof it -may happen that the heat resistance of the treatedmetals will be somewhat lowered, but on the other hand there will be the advantage that the produced protective layers will be of higher ductility and thatthe working of the treated pieces will be considerably improved.
  • the ductility of the produced protective layers may be regulated by varying the content of free metallic aluminium in the hardening powder.
  • a regulation of the behaviour of the protective layers, although in a smaller limit, may also be obtained by applying the same'variations to the hardening powders with) higher contents of aluminium (15 to 3 What I claim is:
  • Processior the production ofdifi'used protective layers upon iron which comprises heating the iron w1th a powder composition containing from 8 to of free metallic aluminium.
  • Process for the production-of diffused protective layers upon iron which comprises heating the iron at about 1100 C. with a powder composition containing from 8 to 30% of free metallic aluminium.

Description

Patented May' 7, 1929. i I v I V UNITED STATES PATENT OFFICE.
. mun my, or rmmonr-oN-rnE-mm nsenERsnEm, GERMANY.
PBOCES FOR PRODUCTION D1 DIFFUSED LAYERS ON METALS.
Ho Drawing. Application me October 31, 1927, Serial Iflo. 230,172, and in Germany June-15, 1926.. a
This invention relates to a process for the production of diffused layers on metals.
Various processes have become known for the production of diffused fire-and corro- 5 sionresistant layers of aluminium upon metals such as iron, copper. and the like. Such diffused layers are, as is well known, produced by embeddingthe piece to be improved in a powder of aluminium or aluminium alloys and submitting same to a treatment similar to case-hardening, at temperatures lying between 700 and 1200 G., the preferred temperature being about 1100 C. Ammonium chloride and inert substances such as sand, clay and the like are frequently also admixed with the hardening powder. Useful diffused layers canthus be obtained by means of the hitherto known processes.
The present invention relates 'to afurther development of this process. Ithas been found that the qualityof the protective layer produced can be considerably improved if the metallic aluminium content of the hardening powder is ke t within certain definite limits. These limits lie between 15 and of metallicaluminium. The most favourable content generally lies in the vicinity of 20%. Alterations of and deviations from this optimum can be caused by, the temperature 30 0 treatment, the thickness of the protective layerproduced and particular qualities demanded therefrom, the composition and quality of the material to be improved and the like. If aluminium alloy powders are employed the aforesaid values can be adjusted to correspond to the aluminium content of the alloy in such a manner that the amount of the alloy is calculated on its aluminium content. The hardening powders used' according to 40 the invention must obviously exhibit as uniform a dispersion of the aluminium as possible, since the aluminium concentration'would be altered by irregularities in the distribution of the-aluminium.-
In order to ensure this uniformity duringf I all operating conditions, the (powders are preferablyp'roduced by first ad ing the aluminium in small amounts up to 8% to the inert base mass consisting of clay, alumina and the like. This mixture is then preferably ignited in an inert atmosphere (in order to reduce waste by the aluminium burning) and after renewed" addition of aluminium within the same limits, it is submitted to the same treatment, these operations being continued until the desired aluminium content is obtained. This method of operation has proved especially advantageous owing to the fact that when larger amounts of aluminium than those above mentioned are added to the inert material it may occur that the individual aluminium particles. agglomerate and thus render it impossible to produce a hardening powder of uniform distribution.
.In the case of an addition within the limits above set forth, the aluminium need not be added in a very finely subdivided form but it is sufficient if it is employed in the form of chi s, such as are obtainedin works.
11 heating to the above mentioned temperatures, the aluminium shows a marked tendency to diffuse. It disseminates very finely and uniformly in the base mass.
In order to obtain a hardening powder containing about 20% aluminium, starting from pure alumina, the aluminium is added in threev stages; heating to the aforesaid temperature being effected at each stage. It is preferable to employ such base masses as already contain. a certain amount of aluminium. Aluminium scrap obtained in aluminium foundries, contain aluminium in a sufliciently fine form and in amounts of 10 to 15%. If these are ground and worked up so as to separate the coarser particles, a starting ma terial which is very suitable for the production of hardening powders can be obtained.
In continuous operations the powder can always be employed over again. It'is only necessary to make up the metallic aluminium lost by the powder during the diffusion treatment, by the addition of aluminium or aluminium alloys. In the case of relatively high losses of aluminium (above 8%) this is offected inthe above-described manner. If the lossis less, it is suflicient merely to admix a corresponding amount of aluminium with the powder, as uniformly as possible.
. The process of the invention has the advantage that the protective layer upon the.
pieces to be subsequently worked up,the work of grinding 'isconsiderably reduced. Moreover the diffusion process itself, has the'advantage that it is considerably shortened and simplified.
The advantages of the above-described that these are relatively finely subdivided and that they do not react, or do not react to any substantial extent, with the metal of the powder or with the piece to be treated.
In special cases the lower limit of the metallic aluminium content the hardening powder may be advantageously diminished to approximately 8%. In consequence'thereof it -may happen that the heat resistance of the treatedmetals will be somewhat lowered, but on the other hand there will be the advantage that the produced protective layers will be of higher ductility and thatthe working of the treated pieces will be considerably improved.
The ductility of the produced protective layers may be regulated by varying the content of free metallic aluminium in the hardening powder. A regulation of the behaviour of the protective layers, although in a smaller limit, may also be obtained by applying the same'variations to the hardening powders with) higher contents of aluminium (15 to 3 What I claim is:
1. Processior the production ofdifi'used protective layers upon iron which comprises heating the iron w1th a powder composition containing from 8 to of free metallic aluminium.
2. Process for the production-of diffused protective layers upon iron which comprises heating the iron at about 1100 C. with a powder composition containing from 8 to 30% of free metallic aluminium.
' 3. Process of making a powder composition for the production of protective layers on' metallic iron which comprises admixing with an inert material finely divided metallic aluminium in amounts up to 8%, igniting the' mixture in an inert atmosphere at a temperature of from 700 to 1200? C. and repeating the addition of aluminium and the ignition until the desired quantity of metallic aluminium up to 30% is obtained in the powder.
In testimony whereof I ailix my signature.
DR. EMIL DAY.
US230172A 1926-06-15 1927-10-31 Process for production of diffused layers on metals Expired - Lifetime US1711603A (en)

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Cited By (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2536774A (en) * 1946-03-07 1951-01-02 Diffusion Alloys Corp Process of coating ferrous metal and heat pack mixture therefor
US2643959A (en) * 1950-05-29 1953-06-30 Manufacturers Chemical Corp Process for the protective treatment of iron
US3065108A (en) * 1960-01-07 1962-11-20 Chromalloy Corp Method of applying a chromium coating to high temperature resistant materials
US3274019A (en) * 1964-11-06 1966-09-20 Alton V Oberholtzer Impregnation and coating with splitoffs of vermiculite and products thereof
US3535103A (en) * 1968-04-10 1970-10-20 Atomic Energy Commission Method of making metal alloy powders
US4043542A (en) * 1975-09-30 1977-08-23 Sumitomo Metal Industries Limited Tuyeres for a blast furnace

Cited By (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2536774A (en) * 1946-03-07 1951-01-02 Diffusion Alloys Corp Process of coating ferrous metal and heat pack mixture therefor
US2643959A (en) * 1950-05-29 1953-06-30 Manufacturers Chemical Corp Process for the protective treatment of iron
US3065108A (en) * 1960-01-07 1962-11-20 Chromalloy Corp Method of applying a chromium coating to high temperature resistant materials
US3274019A (en) * 1964-11-06 1966-09-20 Alton V Oberholtzer Impregnation and coating with splitoffs of vermiculite and products thereof
US3535103A (en) * 1968-04-10 1970-10-20 Atomic Energy Commission Method of making metal alloy powders
US4043542A (en) * 1975-09-30 1977-08-23 Sumitomo Metal Industries Limited Tuyeres for a blast furnace

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