US2067308A - Stainless copper base alloys - Google Patents

Stainless copper base alloys Download PDF

Info

Publication number
US2067308A
US2067308A US751090A US75109034A US2067308A US 2067308 A US2067308 A US 2067308A US 751090 A US751090 A US 751090A US 75109034 A US75109034 A US 75109034A US 2067308 A US2067308 A US 2067308A
Authority
US
United States
Prior art keywords
chromium
copper
nickel
alloy
manganese
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
US751090A
Inventor
Richard A Wilkins
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.)
Revere Copper and Brass Inc
Original Assignee
Revere Copper and Brass Inc
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
Priority claimed from US673768A external-priority patent/US1983205A/en
Application filed by Revere Copper and Brass Inc filed Critical Revere Copper and Brass Inc
Priority to US751090A priority Critical patent/US2067308A/en
Application granted granted Critical
Publication of US2067308A publication Critical patent/US2067308A/en
Anticipated expiration legal-status Critical
Expired - Lifetime legal-status Critical Current

Links

Classifications

    • CCHEMISTRY; METALLURGY
    • C22METALLURGY; FERROUS OR NON-FERROUS ALLOYS; TREATMENT OF ALLOYS OR NON-FERROUS METALS
    • C22CALLOYS
    • C22C9/00Alloys based on copper
    • C22C9/06Alloys based on copper with nickel or cobalt as the next major constituent

Definitions

  • copper base alloys can be produced by compounding copper, nickel and chromium in 'proper proportions particularly when suitable precautions are taken to secure solution of the chromium and to prevent deleterious secondary compounds.
  • alloys may be readily cold and hot rolled into sheets and may be otherwise attenuated while cold or'hot by usual mill processes to produce various shapes.
  • the alloy maybe compounded with or without zinc, but preferably with it except as hereinafter mentioned, as its presence it has been found facilitates the working of the alloy particularly when it is to be annealed between the attenuating steps in the mill processes.
  • the alloy preferably is compounded with an additional constituent or constituents, hereinafter for convenience in terminology referred to as chromium incorporators, which will insure protecting the chromium from oxidation and insure its solution, and preferably also insure eliminating the effect on the nickel of any sulphur that may be present.
  • the chromium when melted in or with cupro-nickel is liable to come off asa slag or be in the form aflinity than chromium for oxygen and a greater afiinity than nickel for sulphur, any possibility of oxidation of the chromium and formation of nickel-sulphid is prevented effectively by use of this metal.
  • the manganese-sulphid has no appreciable eifect upon the workability of the alloy, 5 and any excess of manganese, over that necessary to secure these results within the range of metals hereinafter stated, enters into solution and augments the eifect of the nickel as a whitener for the alloy.
  • magnesium and tin may be employed as a substitute for manganese as a so-called chromium incorporator.
  • the magnesium will prevent any possibility of oxidation of the chromium and formation of nickel-sul- 15 phid, while the tin will insure the solution of the chromium.
  • magnesium precaution should be taken not to employ an amount thereof materially in excess of that necessary to take up the oxygen and sulphur, small amounts of magnesium in excess of this, say in the order of 0.25% uncombined metal, deleteriously affecting the physical properties of the alloy within the ranges of metals herein stated.
  • magnesium with tin is employed as a substitute for manganese the zinc may be omitted, and in practice ordinarily is.
  • the tensile strength of the alloy may be increased and controlled by addition of small amounts of vanadium, say from traces 30 up to 0.1%, this metal also much improving the cold working properties of the alloy and its duetility and elongation.
  • the amount of nickel may be varied to vary the color of the alloy. With a high nickel con- 35 tent of about 18% a bright, clear white metal characteristic of the color of stainless steel is secured. By decreasing the nickel content to 10% and below alloys of warmer tones are obtained, with a suggestion of a rose or pinkish 40 tint underlying the white, which warmer tones are desirable for architectural work.
  • the nickel content should ordinarily not exceed approximately from 20 to 22%, as above these values the alloy becomes increasingly'difiicult to work. On 45 the other hand, the nickel content should not ordinarily be less than approximately from 4 to 5%, as below these values the alloy loses its characteristic color and ceases to be stainless.
  • the copper content should be relatively high, 5 and 'ordinarilynot less than approximately 65% of the alloy, as with lower copper values the alloy becomes increasingly brittle and difflcult to work. Further, the copper content should not exceed approximately when zinc and man- 55 the 'alloy within the ranges of other constituents hereinafter mentioned, the sum of the copper and nickel should not be less than approximately 810%, or when zinc is present exceed approximately 9 5% or in the absence of zinc exceed approximately It has. been found that the amount of chromium ordinarily should not exceed approximately 5% as values in excess of this make the alloy difiicult to work, and ordinarily should not be less than approximately 0.5% to insure that the alloy is stainless.
  • the amount thereof should vary approximately linearly and inversely with the amount of copper, satisfactory results ordinarily being secured when the amount of chromium is within plusorminus 25% of the value determined by this ratio, so long as it is not materially above the maximum or below the minimum values thereof of 5 and 0.5% respectively.
  • the amount of manganese should vary approximately linearly and directly with the amount of chromium, it ordinarily being satisfactory when the amount of manganese is within plus or minus 25% of the value determined by this ratio.
  • magnesium with tin When magnesium with tin is em- ,ployed as a substitute for manganese, to prevent the presence of a deleterious excess of magnesium, over that necessary to prevent-both oxidation of the chromium and formation of deleterious amounts of nickel-sulphid, the amount of magnesium should ordinarily not exceed approximately 5%, and, to insure satisfactory ef.- fects, should ordinarily not beless than approximately 0.25%, while within the range of chromium above stated the amount of tin should not exceed approximately 0.5% or be less than approximately 0.1%.” To secure best results, the specific amounts of magnesium and tin should, like the manganese, ordinarily vary approximately. linearly and directly'with the amount of chromium,
  • the amounts of magnesium and tin are within plus or minus 25% of the value determined by this ratio.
  • the zinc which preferably is employed, particularly when man- 'g'anese is used to facilitate incorporation of the chromium, should not exceed approximately 20% of the alloy, as' zinc values in excess of this tend *
  • the general approximate formula for the basic copper, nickel, chromium alloys may be stated as copper 65 to 93 parts, nickel 4to'22 parts, and chro-' mium 0.5 1:05 parts, with the sum of the copper and nickel between and 97 parts.
  • the general approxi- 70 mate formula becomes copper 65 to 93 parts
  • nickel chromium alloys When a chromium incorporator is employed with these basic copper, nickel chromium alloys, 0.25 to 5 parts manganese (or 0.25 to 5 parts magnesium plus 0.1 to 0.5 parts tin) ,may be employed, When both zinc and the chromium incorporator are employed with these basic copper, nickel, chromium alloys, which maybe done if desired, the'zinc should be largely substituted for part of the copper, in which case the general approximate formula for the alloys becomes copper 65 to nickel 5 to 22%; chromium 0.5 to 5%, manganese 0.25.
  • the chromium within the range thereof stated preferably should vary approximately linearly and inversely with' the amount of copper and the manganese; magnesium and tin within the ranges thereof statedpreferably should; vary approximately linearly and directly with the amount of chromium.
  • Alloys consisting of copper 65 to 93 parts, nickel 4 to 22 parts, with the sum of the copper and nickel 80 to 9'7 parts, chromium 0.5 to 5 parts, and manganese 0.5 to 5 parts,have the following approximate pe'rcentage composition: copper 66.5 to 95.3%, nickel 3.6 to 25%, with the sum of the copper and nickel 89 to 99%, chromium 0.5 to. 5.5%, and manganese 0.5 to 5.5%.
  • the manganese may then be added in the form of a copper alloy rich in manganese, say one containing 25% manganese.
  • the chromium may be added in the form of a copper alloy rich in chromium, say one containing 10% chromium, and then the vanadium may be added in the same way.
  • the zinc may be added in the form of brass to cool the melt to about 2000 F. just before pouring. When the alloy contains tin the same may be added to the molten copper and nickel in the form of bronze scrap, after which the magnesium and chromium may be added, in the form of a copper alloy rich in both these metals, shortly before pouring.
  • I claim 1 Stainless, hot and cold workable, white metal alloys containing copper 66.5 to 95.3%, nickel 3.6 to 25%, chromium 0.5 to 5.5%, manganese 0.5 to 5.5%, the sum of the copper and nickel being between 89 and 99%, the amount of chromium varying roughly linearly and inversely with the amount of copper within the ranges of chromium and copper specified, the

Landscapes

  • Chemical & Material Sciences (AREA)
  • Engineering & Computer Science (AREA)
  • Materials Engineering (AREA)
  • Mechanical Engineering (AREA)
  • Metallurgy (AREA)
  • Organic Chemistry (AREA)
  • Conductive Materials (AREA)

Description

Patented Jan. 12, 1937 PATENT OFFICE STAINLESS COPPER BASE ALLOYS Richard A. Wilkins, Rome, N. Y., assignor to Revere Copper and Brass Incorporated, Rome, N. Y., a. corporation of Maryland No Drawing. Original application May 31,1933,
Serial No. 673,768.
Divided and this application November 1, 1934, Serial No. 751,090
6 Claims.
This application is a division of my co-pending application Serial No. 673,768, filed May 31, 1933.
My invention, which relates to stainless copper base alloys, and has among its objects the production of alloys of this kind which may be readily worked into sheets and other forms by usual millprocesses, will be best-understood from the following description of several examples of 10 the alloy compounded according to the invention, the scope of which latter will be more particularly pointed out in the appended claims.
Heretofore. copper base alloys containing nickel and chromium have been employed in practice only for castings. For economic reasons it has been impractical to roll or otherwise mechanically work such prior alloys as they are brittle,
copper base alloys can be produced by compounding copper, nickel and chromium in 'proper proportions particularly when suitable precautions are taken to secure solution of the chromium and to prevent deleterious secondary compounds.
These alloys may be readily cold and hot rolled into sheets and may be otherwise attenuated while cold or'hot by usual mill processes to produce various shapes. The alloy maybe compounded with or without zinc, but preferably with it except as hereinafter mentioned, as its presence it has been found facilitates the working of the alloy particularly when it is to be annealed between the attenuating steps in the mill processes. Further, the alloy preferably is compounded with an additional constituent or constituents, hereinafter for convenience in terminology referred to as chromium incorporators, which will insure protecting the chromium from oxidation and insure its solution, and preferably also insure eliminating the effect on the nickel of any sulphur that may be present. In the absence of protecting the chromium from oxidation, the chromium when melted in or with cupro-nickel is liable to come off asa slag or be in the form aflinity than chromium for oxygen and a greater afiinity than nickel for sulphur, any possibility of oxidation of the chromium and formation of nickel-sulphid is prevented effectively by use of this metal. The manganese-sulphid has no appreciable eifect upon the workability of the alloy, 5 and any excess of manganese, over that necessary to secure these results within the range of metals hereinafter stated, enters into solution and augments the eifect of the nickel as a whitener for the alloy. I 10 As a substitute for manganese as a so-called chromium incorporator, small amounts of magnesium and tin may be employed. The magnesium will prevent any possibility of oxidation of the chromium and formation of nickel-sul- 15 phid, while the tin will insure the solution of the chromium. In employing magnesium precaution should be taken not to employ an amount thereof materially in excess of that necessary to take up the oxygen and sulphur, small amounts of magnesium in excess of this, say in the order of 0.25% uncombined metal, deleteriously affecting the physical properties of the alloy within the ranges of metals herein stated. When magnesium with tin is employed as a substitute for manganese the zinc may be omitted, and in practice ordinarily is.
When desired the tensile strength of the alloy may be increased and controlled by addition of small amounts of vanadium, say from traces 30 up to 0.1%, this metal also much improving the cold working properties of the alloy and its duetility and elongation.
The amount of nickel may be varied to vary the color of the alloy. With a high nickel con- 35 tent of about 18% a bright, clear white metal characteristic of the color of stainless steel is secured. By decreasing the nickel content to 10% and below alloys of warmer tones are obtained, with a suggestion of a rose or pinkish 40 tint underlying the white, which warmer tones are desirable for architectural work. The nickel content should ordinarily not exceed approximately from 20 to 22%, as above these values the alloy becomes increasingly'difiicult to work. On 45 the other hand, the nickel content should not ordinarily be less than approximately from 4 to 5%, as below these values the alloy loses its characteristic color and ceases to be stainless.
The copper content should be relatively high, 5 and 'ordinarilynot less than approximately 65% of the alloy, as with lower copper values the alloy becomes increasingly brittle and difflcult to work. Further, the copper content should not exceed approximately when zinc and man- 55 the 'alloy within the ranges of other constituents hereinafter mentioned, the sum of the copper and nickel should not be less than approximately 810%, or when zinc is present exceed approximately 9 5% or in the absence of zinc exceed approximately It has. been found that the amount of chromium ordinarily should not exceed approximately 5% as values in excess of this make the alloy difiicult to work, and ordinarily should not be less than approximately 0.5% to insure that the alloy is stainless. It has further been found, that'to secure the desirable properties of the alloy within this range of chromium, the amount thereof should vary approximately linearly and inversely with the amount of copper, satisfactory results ordinarily being secured when the amount of chromium is within plusorminus 25% of the value determined by this ratio, so long as it is not materially above the maximum or below the minimum values thereof of 5 and 0.5% respectively.
It has been found that under ordinary conditions amounts of manganese less than 0.25% will not insure satisfactory results, and that amounts in excess of 5% are likely to cause the alloy .to
become brittle and refractory with the range of chromium abovestated. Further, to secure best results, the amount of manganese should vary approximately linearly and directly with the amount of chromium, it ordinarily being satisfactory when the amount of manganese is within plus or minus 25% of the value determined by this ratio. When magnesium with tin is em- ,ployed as a substitute for manganese, to prevent the presence of a deleterious excess of magnesium, over that necessary to prevent-both oxidation of the chromium and formation of deleterious amounts of nickel-sulphid, the amount of magnesium should ordinarily not exceed approximately 5%, and, to insure satisfactory ef.- fects, should ordinarily not beless than approximately 0.25%, while within the range of chromium above stated the amount of tin should not exceed approximately 0.5% or be less than approximately 0.1%." To secure best results, the specific amounts of magnesium and tin should, like the manganese, ordinarily vary approximately. linearly and directly'with the amount of chromium,
' satisfactory results ordinarily being secured when to make the alloy brittle.
the amounts of magnesium and tin are within plus or minus 25% of the value determined by this ratio.
As hereinbefore mentioned, the zinc, which preferably is employed, particularly when man- 'g'anese is used to facilitate incorporation of the chromium, should not exceed approximately 20% of the alloy, as' zinc values in excess of this tend *The general approximate formula for the basic copper, nickel, chromium alloys may be stated as copper 65 to 93 parts, nickel 4to'22 parts, and chro-' mium 0.5 1:05 parts, with the sum of the copper and nickel between and 97 parts. When zinc 'is added to these basic alloys, the general approxi- 70 mate formula becomes copper 65 to 93 parts,
U zinc the balance to make 100 parts, with the sum of the copper andnickel as before; and if the alloys contain vanadium the same may be substituted for an equal part of the zinc.
nickel 4 to 22 parts, chromium 0.5 to 5 parts, and
When a chromium incorporator is employed with these basic copper, nickel chromium alloys, 0.25 to 5 parts manganese (or 0.25 to 5 parts magnesium plus 0.1 to 0.5 parts tin) ,may be employed, When both zinc and the chromium incorporator are employed with these basic copper, nickel, chromium alloys, which maybe done if desired, the'zinc should be largely substituted for part of the copper, in which case the general approximate formula for the alloys becomes copper 65 to nickel 5 to 22%; chromium 0.5 to 5%, manganese 0.25. to 5% (or magnesium 0.25 to 5% plus tin 0.1 to 0.5%) and zinc the balance, the sum of the copper and nickel being between 80 and 95%, any vanadium employed being substituted for an equal part of the zinc. As has hereinbefore been mentioned, inall these cases the chromium within the range thereof stated preferably should vary approximately linearly and inversely with' the amount of copper and the manganese; magnesium and tin within the ranges thereof statedpreferably should; vary approximately linearly and directly with the amount of chromium. Alloys consisting of copper 65 to 93 parts, nickel 4 to 22 parts, with the sum of the copper and nickel 80 to 9'7 parts, chromium 0.5 to 5 parts, and manganese 0.5 to 5 parts,have the following approximate pe'rcentage composition: copper 66.5 to 95.3%, nickel 3.6 to 25%, with the sum of the copper and nickel 89 to 99%, chromium 0.5 to. 5.5%, and manganese 0.5 to 5.5%.
As suitable alloys for fabricating sheets for architectural purposes, the following give satisfactory results:
a Percent Copper 75 Nickel, 18 Chromium 0.5 to 1 Zinc Balance Percent Copper 68 Nickel 19 Chromium 3to 3.5 Manganese 4 Vanadium 0.02to 0.03 Zinc Balance It has been found that excellent alloys satisfactory for ordinary purposes can be compounded according to the invention consisting of I I I Percent Copper 65 to 93 Nickel 8 to 18 Chromium"; 1to4 Tin l 0.2 to 0.4 ,Magnesium 1to4 Vanadium Traces to 0.1
ran excellent alloy of this series consisting of Percent Copper 84 Nickel s ,Q 11
Chromium- -3.5 Tin 0.25 Magnesium 1 1.4 Vanadium Trace asuitable method of compounding the above alloys the copper and nickel may be melted together and thertemperature of the melt raised to about 2300 F. The manganese may then be added in the form of a copper alloy rich in manganese, say one containing 25% manganese. The chromium may be added in the form of a copper alloy rich in chromium, say one containing 10% chromium, and then the vanadium may be added in the same way. The zinc may be added in the form of brass to cool the melt to about 2000 F. just before pouring. When the alloy contains tin the same may be added to the molten copper and nickel in the form of bronze scrap, after which the magnesium and chromium may be added, in the form of a copper alloy rich in both these metals, shortly before pouring.
It will be understood that small proportions of other metals than those herein mentioned may be added to the alloy to give it special characteristics when they do not to a material extent change the hereinbefore mentioned desirable physical and chemical properties of the alloy, and also that wide deviations may be made from the embodiments of the invention herein described without departing from the spirit of the invention.
I claim 1. Stainless, hot and cold workable, white metal alloys containing copper 66.5 to 95.3%, nickel 3.6 to 25%, chromium 0.5 to 5.5%, manganese 0.5 to 5.5%, the sum of the copper and nickel being between 89 and 99%, the amount of chromium varying roughly linearly and inversely with the amount of copper within the ranges of chromium and copper specified, the
copper and nickel constituting substantially the balance of the alloy with respect to the other elements specified.
2. Stainless hot and cold workable, white metal alloys containing copper 66.5 to 95.3%,- nickel 3.6 to 25%, chromium 0.5 to 5.5%, manganese 0.5 to 5.5%, the sum of the copper and nickel being between 89 and 99%, the amount of manganese varying roughly linearly and directly with the amount of chromium, the copper and nickel constituting substantially the balance of the alloy with respect to the other elements specified.
3. Stainless, hot and cold workable, white metal alloys containing copper 66.5 to 95.3% nickel 3.6 to 25%, chromium 0.5 to 5.5%, manganese 0.5 to 5.5%, the sum of the copper and nickel being between 89 and 99%, the amount of chromium varying roughly linearly and. inversely with the amount of copper within the ranges of chromium and copper specified, and the amount of manganese varying roughly linearly and directly with the amount of chromium, the copper and nickel constituting substantially the balance of the alloy with respect to the other elements specified.
4. The alloys according to claim 1 containing appreciable amounts up to 0.1% vanadium.
5. The alloys according to claim 2 containing appreciable amounts up to 0.1% vanadium.
6. The alloys according to claim 3 containing appreciable amounts up to 0.1% vanadium.
RICHARD A. WILKINS.
US751090A 1933-05-31 1934-11-01 Stainless copper base alloys Expired - Lifetime US2067308A (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
US751090A US2067308A (en) 1933-05-31 1934-11-01 Stainless copper base alloys

Applications Claiming Priority (2)

Application Number Priority Date Filing Date Title
US673768A US1983205A (en) 1933-05-31 1933-05-31 Stainless copper base alloy
US751090A US2067308A (en) 1933-05-31 1934-11-01 Stainless copper base alloys

Publications (1)

Publication Number Publication Date
US2067308A true US2067308A (en) 1937-01-12

Family

ID=27101007

Family Applications (1)

Application Number Title Priority Date Filing Date
US751090A Expired - Lifetime US2067308A (en) 1933-05-31 1934-11-01 Stainless copper base alloys

Country Status (1)

Country Link
US (1) US2067308A (en)

Similar Documents

Publication Publication Date Title
US3146096A (en) Weldable high strength magnesium base alloy
US2253502A (en) Malleable iron
US2067308A (en) Stainless copper base alloys
US2067307A (en) Stainless copper base alloy
US1983205A (en) Stainless copper base alloy
US2683662A (en) Manufacture of iron and steel and products obtained
US2736648A (en) Low metalloid enameling steel and method of producing same
US2067306A (en) Alloys
US935863A (en) Alloy and process for its production.
US2098081A (en) Aluminum alloy
US1580443A (en) Gold alloy
US3512961A (en) Fine grained white gold alloy
US1852442A (en) Zinc-base die-casting alloy
US2295180A (en) Copper alloy
US3772092A (en) Copper base alloys
US2683663A (en) Stainless steel and method of production
US2616797A (en) Alloy for the preparation of titanium-boron steel
US1480706A (en) Forgeable alloy of iron and nickel
US2027330A (en) Welding rod alloys
US3607237A (en) Ferritic stainless steel
US1700460A (en) Metallurgical process
US2385685A (en) Magnesium base alloy
US1986208A (en) Nonstainable steel alloy
US979394A (en) Process for the production of alloys of tin and titanium.
US2041042A (en) Aluminum alloy