US2996378A - Electrical resistance wire - Google Patents

Electrical resistance wire Download PDF

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Publication number
US2996378A
US2996378A US761293A US76129358A US2996378A US 2996378 A US2996378 A US 2996378A US 761293 A US761293 A US 761293A US 76129358 A US76129358 A US 76129358A US 2996378 A US2996378 A US 2996378A
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wire
temperature
nickel
ohm
resistance
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US761293A
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Edward E Edmunds
Arthur S Lichter
Poch Stephen
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Molecu-Wire Corp
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Molecu-Wire Corp
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    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01BCABLES; CONDUCTORS; INSULATORS; SELECTION OF MATERIALS FOR THEIR CONDUCTIVE, INSULATING OR DIELECTRIC PROPERTIES
    • H01B1/00Conductors or conductive bodies characterised by the conductive materials; Selection of materials as conductors
    • H01B1/02Conductors or conductive bodies characterised by the conductive materials; Selection of materials as conductors mainly consisting of metals or alloys
    • CCHEMISTRY; METALLURGY
    • C22METALLURGY; FERROUS OR NON-FERROUS ALLOYS; TREATMENT OF ALLOYS OR NON-FERROUS METALS
    • C22CALLOYS
    • C22C19/00Alloys based on nickel or cobalt
    • C22C19/03Alloys based on nickel or cobalt based on nickel
    • C22C19/05Alloys based on nickel or cobalt based on nickel with chromium
    • C22C19/058Alloys based on nickel or cobalt based on nickel with chromium without Mo and W

Definitions

  • This invention relates to electrical resistance alloys, to methods of processing wire made from such alloys to produce products with controlled temperature coefiicients of resistivity and to the novel products resulting therefrom. More particularly it relates to alloy compositions containing from to 30% by weight Cr, between about 2 and 5% by weight Al, between 1% and 4% by weight C0, balance substantially all nickel except for incidental amounts of trace elements, deoxidizers, degasihers and impurities incidental to the normal production of the type of alloy in commercial amounts and to a heat treatment in the range of 800 to 1200 F. for relatively limited time intervals, usually shorter than 45 minutes after the alloy has been fabricated into wire by combinations of hot working and cold working and prior to its incorporation into a finished article of manufacture such as a potentiometer, resistor or other electrical apparatus.
  • One object of the invention is to production of alloys from which wire with desirably low coefficients of resistivity and desirably high electrical resistances is reproducibly obtained.
  • Another object is to provide a wire product having a controlled temperature coefiicient of resistance which may be positive, or negative, or zero according to the specific processing to which the wire is subjected.
  • Still a further object is to provide an alloy which may be formed into wire having a combination of high resistance, low temperature coefiicient of resistance, improved stability and uniformity of the relation between resistance and temperature.
  • Patent 2,460,590 may be regarded as typical of the prior art in this field.
  • the effects of modifying 80/20 Ni/ Cr alloys by the incorporation therein of Al and combinations of Al and Fe and Al and Mn, together with a heat treatment subsequent to annealing at temperatures of upwards of 1700 F. and usually upwards of 1900 F. are set forth as responsible for improvements in the two constants of principal interest in alloys of this class, namely temperature coefficient of resistance and specific resistance. While the results reported in the above mentioned patents indicated that heat treatment of the annealed alloy produced improved products, no
  • the improved alloys of the present invention may be broadly defined as those containing between 10% and 30% by weight Cr; between about 2% and 5% by weight Al; between about 1% and 4% Co and the balance nickel, except for deoxidizers, degasifiers and metallic or non-metallic contaminants whose presence is incidental to manufacture from secondary metal raw materials.
  • Preferred alloys in accordance with the present invention are those containing between about 19% and 21% Cr, between about 2.7% and 3.2% A1; from 1.75% to 2.5% Co, not more than 0.5% Mn, not more than 0.5% Cu, not more than 0.3% Fe, a maximum of 0.05%
  • An alloy was prepared by vacuum melting a charge of suitable composition in an induction furnace. Ingot of the following specific analysis was cast after deoxidation of the melt, in the usual manner:
  • the hot rolled 9/ 32"diameter rod was reduced in size to the desired breakdown diameter of .032" by a series of cold drawing steps, after each of which the wire was annealed, in order to recrystallize the cold worked alloy and to prepare it for the next drawing step.
  • the scheduled dr-a-fts did not reduced the cross sectional area more than 65% through the dies in any one series of cold to yield product with a zero temperature coefiicient as shown in Table I.
  • Ni-Cr-Al alloys containing between 1% and 4% Co may be processed in similar fashion to produce wire having specific resistances of at least 840 ohms per circular mil foot and usually above 900 ohms per circular mil foot and temperature resistance coetficients of substantially less than 0.00002 ohm per ohm C.
  • An electrical resistance Wire having a specific resistance of at least 800 ohms per emf. and a temperature coefiicient of resistivity ofat most .00002 ohm per ohm C over. a temperature range of from minus 85 F. to plus 482 F.
  • said wire comprising a, nickel-base alloy consisting essentially of between about 10% and 30% Cr, between. about 2% and 4% A1, between about 1% and 4% Co and the balance, except for impurities and residuals, nickel which wire has been subjected to a plurality of cold Workings, each followed by an. anneal at a temperature between about 1900 F. and 2150 F.
  • nickel-base 1 alloy consists essentially of the following, by weight; 19%
  • Wire 0.0004" diameter would preferably be annealed at temperatures as low as 1900" F. and wire 0.010 diameter would be annealed at temperatures as high as 2150 F. Thus the final anneal should preferably be between 1900 F. and 2150" F., depending to some extent on the size wire being annealed.
  • the wire was heat treated to impart the combination of low temperature coefficient of resistance and high specific resistance required in electrical resistance alloys of the present type.
  • the alloy Prior to such heat treatment the alloy, after final anneal at 2050 F. had a specific resistance of 755 ohms per emf. and a temperature coefiicient of resistance of 0.000058 ohm per ohm degree centigrade over the temperature range from 85 F. to 482 F.

Description

nite
No Drawing. Filed Sept. 16, 1958, Ser. No. 761,293 4 Claims. (Cl. 75-171) This invention relates to electrical resistance alloys, to methods of processing wire made from such alloys to produce products with controlled temperature coefiicients of resistivity and to the novel products resulting therefrom. More particularly it relates to alloy compositions containing from to 30% by weight Cr, between about 2 and 5% by weight Al, between 1% and 4% by weight C0, balance substantially all nickel except for incidental amounts of trace elements, deoxidizers, degasihers and impurities incidental to the normal production of the type of alloy in commercial amounts and to a heat treatment in the range of 800 to 1200 F. for relatively limited time intervals, usually shorter than 45 minutes after the alloy has been fabricated into wire by combinations of hot working and cold working and prior to its incorporation into a finished article of manufacture such as a potentiometer, resistor or other electrical apparatus.
One object of the invention is to production of alloys from which wire with desirably low coefficients of resistivity and desirably high electrical resistances is reproducibly obtained. 7
Another object is to provide a wire product having a controlled temperature coefiicient of resistance which may be positive, or negative, or zero according to the specific processing to which the wire is subjected.
Still a further object is to provide an alloy which may be formed into wire having a combination of high resistance, low temperature coefiicient of resistance, improved stability and uniformity of the relation between resistance and temperature.
These and other objects will be apparent from the more complete disclosure of preferred aspects of our invention which follows.
The use of wire products of nickel-chromium alloys of the 80/ type is known and taught in Patents 2,585,- 613 and 2,63 8,425 for example, and it is also known that such alloys may be improved for certain purposes by the incorporation therein of small amounts of Al as taught in US. Patent 2,533,735 for example, or small amounts of Al and Cu, as taught in Patents 2,293,878 and 2,343,040, or small amounts of Al and Fe as taught in Patent 2,460,590, or small amounts of Al and Mn as taught in 2,533,736. These and other prior art disclosures reveal that to produce product with temperature coeflicients of resistance below 0.00008 and specific resistances of at least 800 ohms per circular mil foot, tedious and expensive processing was required when working with such alloys.
Patent 2,460,590 may be regarded as typical of the prior art in this field. In this patent, the effects of modifying 80/20 Ni/ Cr alloys by the incorporation therein of Al and combinations of Al and Fe and Al and Mn, together with a heat treatment subsequent to annealing at temperatures of upwards of 1700 F. and usually upwards of 1900 F. are set forth as responsible for improvements in the two constants of principal interest in alloys of this class, namely temperature coefficient of resistance and specific resistance. While the results reported in the above mentioned patents indicated that heat treatment of the annealed alloy produced improved products, no
to have a specific resistance at least as high as 900 ohms ltates atent ice per circular mil foot and a temperature coeflicient of less than 0.00002 ohm per ohm C.
By suitably processing the alloys of the present invention, stable products with specific resistances at least as high as 840 ohms per circular mil foot and usually higher than 900 ohms per circular mil foot and temperature c0- efficients no greater than .00002 max. over a temperature range of 85 F. to 482 F. are readily and reproducibly obtained.
We have now discovered that the addition of cobalt to Ni-Cr-Al alloys such as those above disclosed, in place of iron, copper, manganese or other previously employed modifiers results in a product which is much more amenable to processing and from which much more readily reproducible results are obtainable.
While We do not wish to be bound by any particular theory as to why such properties are possessed by the Ni-Cr-Al Co alloys of the present invention, it is possible that the close-packed hexagonal structure possessed by cobalt and not found in other previously employed additives, contributes stability and uniformity to the products formed of alloys containing significant amounts of cobalt within the range specified by us. It is also possible that the close-packed hexagonal lattice characteristic of cobalt acts as a key to lock in the properties and to resist changes in same. It may be further noted that cobolt has the lowest compressibility of the commonly used transition elements and this indicates a stronger bonding and consequently an increased atomic cohesion. Other factors which may be responsible, in part, for the enhanced properties of alloys produced in accordance with our invention are the high anisotropy constant and the relatively low magnetostriction constant possessed by cobalt, as compared with iron, copper and manganese;
Essentially, as indicated above, the improved alloys of the present invention may be broadly defined as those containing between 10% and 30% by weight Cr; between about 2% and 5% by weight Al; between about 1% and 4% Co and the balance nickel, except for deoxidizers, degasifiers and metallic or non-metallic contaminants whose presence is incidental to manufacture from secondary metal raw materials.
Preferred alloys in accordance with the present invention are those containing between about 19% and 21% Cr, between about 2.7% and 3.2% A1; from 1.75% to 2.5% Co, not more than 0.5% Mn, not more than 0.5% Cu, not more than 0.3% Fe, a maximum of 0.05%
C and less than 0.005% of P or S, the balance nickel, except for minor amounts of deoxidizers and degasifiers such as Zr, Ti, Si and the like, totalling less than 0.5%.
In the example which follows the processing of one specific alloy Will be set forth in detail, but it is to be understood that this is intended to be illustrative rather than limitative of our invention.
An alloy was prepared by vacuum melting a charge of suitable composition in an induction furnace. Ingot of the following specific analysis was cast after deoxidation of the melt, in the usual manner:
Percent by weight Chromium 19.18 Aluminum 2.72 Cobalt 2.40 Iron .L- 0.27 Manganese 0.46 Copper ;I 0.16 Silicon' 0.11 Carbon 0.015 Sulfur 0.005 Phosphorus 0.002 Nickel Balance 'Ihe melt was cast into ingot and processed in the usual manner to'hot rolled rod, 9/32" in diameter and thence to a convenient intermediate breakdown size of 0.032"diameter preparatory to drawing the rod down to commercial product between 0.0004 and 0.010", for use in electrical apparatus.
The hot rolled 9/ 32"diameter rod was reduced in size to the desired breakdown diameter of .032" by a series of cold drawing steps, after each of which the wire was annealed, in order to recrystallize the cold worked alloy and to prepare it for the next drawing step. The scheduled dr-a-fts did not reduced the cross sectional area more than 65% through the dies in any one series of cold to yield product with a zero temperature coefiicient as shown in Table I.
TABLE I Properties of 0.005" diameter wire annealed at temperaat 1100 F. for minutes It will be seen, from the above, that alloys containing cobalt in the specified amount were amenable to processing to produce electric resistance Wire products with greatly enhanced properties, as compared with those heretofore obtainable. i
Other Ni-Cr-Al alloys containing between 1% and 4% Co may be processed in similar fashion to produce wire having specific resistances of at least 840 ohms per circular mil foot and usually above 900 ohms per circular mil foot and temperature resistance coetficients of substantially less than 0.00002 ohm per ohm C.
We claim:
, 1, An electrical resistance Wire havinga specific resistance of at least 800 ohms per emf. and a temperature coefiicient of resistivity ofat most .00002 ohm per ohm C over. a temperature range of from minus 85 F. to plus 482 F. said wire comprising a, nickel-base alloy consisting essentially of between about 10% and 30% Cr, between. about 2% and 4% A1, between about 1% and 4% Co and the balance, except for impurities and residuals, nickel which wire has been subjected to a plurality of cold Workings, each followed by an. anneal at a temperature between about 1900 F. and 2150 F. to recrystallize the cold worked productgand which wire has been thereafter subjected to a further heat treatmentt at a ternperature between about 800 F. and 1200 F. for an interval between about 15 minutes and 45 minutes to develop an electrical resistance wire product having a specific resistance of at least 800 ohms and a temperature coeificient of resistivity below 0. 00002 ohm per ohm per degree centigrade.
2. The wire product of claim '1 wherein the nickel-base 1 alloy consists essentially of the following, by weight; 19%
Temperature Basic Specific coefficient of El0nga Sample anneal res. resistivity ticn, Tensile temp. ohms] (25 C. percent strength r.) emf. 125 0.)
V ohm/011m, C.
Wire 0.0004" diameter would preferably be annealed at temperatures as low as 1900" F. and wire 0.010 diameter would be annealed at temperatures as high as 2150 F. Thus the final anneal should preferably be between 1900 F. and 2150" F., depending to some extent on the size wire being annealed.
After: final anneal, the wire was heat treated to impart the combination of low temperature coefficient of resistance and high specific resistance required in electrical resistance alloys of the present type.
Prior to such heat treatment the alloy, after final anneal at 2050 F. had a specific resistance of 755 ohms per emf. and a temperature coefiicient of resistance of 0.000058 ohm per ohm degree centigrade over the temperature range from 85 F. to 482 F.
Heat treatment in a hydrogen atmosphere at the temperatures indicated below increased the specific resistance and lowered the temperature coeificient of resistance as shown in the following table:
to 21% Cr; 2.7 -to 3.2% A1, 1.75 to 2.5% Co, not more than 0.05% 'C; less than 0.5% Mn; less than 0.5% Cu, less than.0.3% Fe, balance nickel except for impurities and residuals. V
3. A. method of processing a nickel-base electrical resistance element consisting of between 10% and 30% Cr; between 2% and 5% Al; between 1% and 4% Co; balance, except for residuals and impurities, essentially all nickel which comprises cold working the alloy to a wire product; then recrystallizing the cold worked prod uct annealing the cold worked product at a temperature between about 1900" F. and 2150 F.; thereafter heat treating the annealed product for a period of from 15 to 45 minutes at a temperature of between 800 F. and 1200 F., to yield a heat treated wire product whose specific resistance is at least 800 ohms per cmf. and Whose temperature coefficient of resistivity is not greater than .00002 over the temperature range F. to 482 F.
4.. A method of processing a nickel-base electrical resistance element consisting of between 10% and 30% Cr; between 2% and 5% A1; between 1% and 4% Co; balance, except for residuals and impurities, essential all nickel which comprises cold working the alloy to a wire product; then recrystallizing the cold worked product annealing the cold'worked product at a temperature between about 1900" F. and 2150" F.; and thereafter heat treating the annealed product for a period of about 30 minutes at a temperature of about 1100 F., to yield a heat treated wire product whose specific resistance is at least 800 ohms per cmf. and whose temperature coefficient of resistivity is. not greater than 0.00002 over the temperature range 85 F. to 482 F.
References Cited in the file of this patent UNITED STATES PATENTS UNITED STATES PATENT OFFICE CERTIFICATE OF CORRECTION Patent No. 2,996,378 August 15, 1961 Edward E. Edmunds et alo It is hereby certified that error appears in :bhe above numbered patentrequiring correction and that the said Letters Patent should read as corrected below.
Column 3, line 12;, for "reduced" read reciuce column 4, line 19, for "4%", read 5% Signed and sealed this 16th day of January 1962,,
(SEAL) Attest:
ERNEST W. SWIDER DAVID L. LADD Attesting Officer Commissioner of Patents

Claims (1)

1. AN ELECTRICAL RESISTANCE WIRE HAVING A SPECIFIC RESISTANCE OF AT LEAST 800 OHMS PER CMF. AND A TEMPERATURE COEFFICIENT OF RESISTIVITY OF AT MOST .00002 OHM PER OHM *C. OVER A TEMPERATURE RANGE OF FROM MINUS 85*F. TO PLUS 482*F. SAID WIRE COMPRISING A NICKEL-BASE ALLOY CONSISTING ESSENTIALLY OF BETWEEN ABOUT 10% AND 30% CR, BETWEEN ABOUT 2% AND 4% AL, BETWEEN ABOUT 1% AND 4% CO AND THE BALANCE, EXCEPT FOR IMPURITIES AND RESIDUALS, NICKEL WHICH WIRE HAS BEEN SUBJECTED TO A PLURALITY OF COLD WORKINGS, EACH FOLLOWED BY AN ANNEAL AT A TEMPERATURE BETWEEN ABOUT 1900*F. AND 2150*F. TO RECRYSTALLIZE THE COLD WORKED PRODUCT; AND WHICH WIRE HAS BEEN THEREAFTER SUBJECTED TO A FURTHER HEAT TREATMENT AT A TEMPERATURE BETWEEN ABOUT 800*F. AND 1200*F. FOR AN INTERVAL BETWEEN ABOUT 15 MINUTES AND 45 MINUTES TO DEVELOP AN ELECTRICAL RESISTANCE WIRE PRODUCT HAVING A SPECIFIC RESISTANCE OF AT LEAST 800 OHMS AND A TEMPERATURE COEFFICIENT OF RESISTIVITY BELOW 0.00002 OHM PER OHM PER DEGREE CENTIGRADE.
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Cited By (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3167424A (en) * 1961-12-21 1965-01-26 Wells Mfg Company Alloy for valve seat insert castings
US3406058A (en) * 1966-07-11 1968-10-15 Molecu Wire Corp Nickel base alloys and electrical resistance wire made therefrom
US3620693A (en) * 1969-04-22 1971-11-16 Gte Electric Inc Ductile, high-temperature oxidation-resistant composites and processes for producing same

Citations (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
GB583807A (en) * 1943-06-30 1946-12-31 Harold Ernest Gresham Nickel base alloy
US2460590A (en) * 1946-05-11 1949-02-01 Driver Harris Co Electric resistance element and method of heat-treatment
US2850384A (en) * 1956-09-26 1958-09-02 Driver Co Wilbur B Electrical resistance alloys

Patent Citations (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
GB583807A (en) * 1943-06-30 1946-12-31 Harold Ernest Gresham Nickel base alloy
US2460590A (en) * 1946-05-11 1949-02-01 Driver Harris Co Electric resistance element and method of heat-treatment
US2850384A (en) * 1956-09-26 1958-09-02 Driver Co Wilbur B Electrical resistance alloys

Cited By (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3167424A (en) * 1961-12-21 1965-01-26 Wells Mfg Company Alloy for valve seat insert castings
US3406058A (en) * 1966-07-11 1968-10-15 Molecu Wire Corp Nickel base alloys and electrical resistance wire made therefrom
US3620693A (en) * 1969-04-22 1971-11-16 Gte Electric Inc Ductile, high-temperature oxidation-resistant composites and processes for producing same

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