US1568422A - Self-induction coil - Google Patents

Self-induction coil Download PDF

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US1568422A
US1568422A US465251A US46525121A US1568422A US 1568422 A US1568422 A US 1568422A US 465251 A US465251 A US 465251A US 46525121 A US46525121 A US 46525121A US 1568422 A US1568422 A US 1568422A
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iron
self
coil
coils
nickel
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US465251A
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Schurer Eugen
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Felten and Guilleaume Carlswerk AG
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Felten and Guilleaume Carlswerk AG
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    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01FMAGNETS; INDUCTANCES; TRANSFORMERS; SELECTION OF MATERIALS FOR THEIR MAGNETIC PROPERTIES
    • H01F1/00Magnets or magnetic bodies characterised by the magnetic materials therefor; Selection of materials for their magnetic properties
    • H01F1/01Magnets or magnetic bodies characterised by the magnetic materials therefor; Selection of materials for their magnetic properties of inorganic materials
    • H01F1/03Magnets or magnetic bodies characterised by the magnetic materials therefor; Selection of materials for their magnetic properties of inorganic materials characterised by their coercivity
    • H01F1/12Magnets or magnetic bodies characterised by the magnetic materials therefor; Selection of materials for their magnetic properties of inorganic materials characterised by their coercivity of soft-magnetic materials
    • H01F1/14Magnets or magnetic bodies characterised by the magnetic materials therefor; Selection of materials for their magnetic properties of inorganic materials characterised by their coercivity of soft-magnetic materials metals or alloys

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  • R, G and A represent the resistance, capacit and leakage per unit of length of a telep one line loaded with self induction coils for the purpose of lessening its attenuation
  • W and L. represent the effective resistance and inductance of one of the coils inserted a distance 8 from one another
  • the attenuation of the telephone line will be The attempted diminution of [3 by increasing L is adversely affected, not only by the second expression in the formula, but also by the fact, that an increase in the inductance by the value 2 per unit of length is accompanied by an increase in the resistance R by the value per unit of length of the effective resistance of the coils.
  • the effective resistance of the coils must therefore be as low as possible.
  • ow and m are constants holding good for a particular periodicity v and for a particular degree of lamination.
  • the formula also shows that the value of A can also be diminished, by reducing the permeability 1. of the iron, but in that case, in order to prevent any change in the inductance of the coil, it is necessary to increase either the number of turns in the winding (and therefore the resistance dig/ or, it these be kept constant, the. weight of the coil. There exists, therefore, a tavourable value for the permeability at which for a given time constant the weight of the coil is at a minimum.
  • Iron-nickel alloys containing a suitable amount of carbon are well known in the art as nickel steels. They exhibit very considerable hysteresis losses.
  • My experiments have shown that if the carbon content is reduced to about 0.09 to 0.06%, the addition of nickel effects a considerable reduct tion in the hysteresis ltlspts of the iron, without at the same time increasing the initial permeabilityas occurs to example with the known iron-silicon alloys used tor transformer and dynamo plates.
  • ltloreover the initial permeability can be reduced to any desired extent by increasing the proportion o'l nickel and can therefore be varied within the aforesaid limits. Since the added nickle also considerably lowers the conductivity of the iron, the eddy-current losses are also reduced.
  • the coetlicient of loss ow of this alloy is less than one third that of pure iron.
  • the initial permeability is about 135.
  • Self-induction coils made of this alloy having an inductance of 0.15 henry and a time constant of 0.04: seconds with a current of 0.5 milliampere at- 800 periods weigh only about. kilograms, whereas the selfinduction coils at the same elec rical constants hitherto used in the artweigh 10.5 kilograms.
  • a indicates the core formed in any well-known manner from a nickel-iron bar, Z) designates the insulating jacket extending around the core, and 0 designates the wire coil.
  • An improved selt-induction coil comprising a magnetization core composed of an iron nickel alloy having 8 to 20 per cent nickel content and a carbon content of .06 to .09 per cent, in. combination with an insulating jacket and a surrounding wire coil,

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  • Chemical & Material Sciences (AREA)
  • Dispersion Chemistry (AREA)
  • Engineering & Computer Science (AREA)
  • Power Engineering (AREA)
  • Soft Magnetic Materials (AREA)

Description

Jan. 5 1926. 1,568,422
E.SCHURER SELF INDUCTION COIL Filed April 28. 1921 AT Y.
Patented Jan. 5, 1926.
UNITED STATES EUGEN SCHU'RER, OF COLOGNE-MULHEIM, GERMANY, ASSIGNOR TO FELTEN AND GUILLEAU'ME CARLSWERK ACTIEN-G-ESELLSCHAFT,
MANY.
0F COLOGNE-1""LHEIM, GER- SELF-INDUCTION COIL.
Application filed April 28, 1921. Serial No. 465,251.
To all whom it may concern:
Be it known that I, EUGEN Sorriinnn, a citizen of Germany, residing at Cologne- Mulheim, Prinz-Wilhelmstrasse Nr. 41, Germany, have invented new and useful Improvements in Self-Induction Coils, of which the following is a specification.
If, R, G and A represent the resistance, capacit and leakage per unit of length of a telep one line loaded with self induction coils for the purpose of lessening its attenuation, and if W and L. represent the effective resistance and inductance of one of the coils inserted a distance 8 from one another, then, as is Well known, the attenuation of the telephone line will be The attempted diminution of [3 by increasing L is adversely affected, not only by the second expression in the formula, but also by the fact, that an increase in the inductance by the value 2 per unit of length is accompanied by an increase in the resistance R by the value per unit of length of the effective resistance of the coils. The effective resistance of the coils must therefore be as low as possible. However, with the kinds of iron hitherto employed in the manufacture of coils,the reduction of W causes the weight of the coils, and therefore the cost of loading, to increase out of all proportion. Hence it has been found advisable to construct the coils, as far as possible, in such a way that, according to the value of R, the value does not exceed 1*) to about 50% of R, the upper limit which is It is comparatively easy to reduce the ohmic resistance of the coil winding to any desired low value by employing wire of suitable sectional area for winding the coils although the size and the weight of the coil is thereby increased. It is, however, more difficult' to reduce the resistance A since, for this purpose it is necessary to discover a suitable kind of iron with sufficiently small loss constants.
The specific watt loss in iron due to hysteresis and eddy currents, with induction B and periodicity is, according to the known formula:
in which ow and m are constants holding good for a particular periodicity v and for a particular degree of lamination.
Since:
p. being the permeability of the iron, it follows that for current strength 2'- and periodicity Th 9 i always y a beit -15% greater than 2. In order to obtain a considerable diminution of A by increasing the volume V, this latter must therefore assume proportions that are far beyond practicable limits. On this account it is desirable to obtain a diminution of A by selecting a kind of iron having a coetiicient of loss at) that is suiiiciently low.
The formula also shows that the value of A can also be diminished, by reducing the permeability 1. of the iron, but in that case, in order to prevent any change in the inductance of the coil, it is necessary to increase either the number of turns in the winding (and therefore the resistance dig/ or, it these be kept constant, the. weight of the coil. There exists, therefore, a tavourable value for the permeability at which for a given time constant the weight of the coil is at a minimum. Exhaustive investigations have shown that this favourable value of permeability is not very decided for small time constants (up to about 0.025 second), but, as the time constant increases, lies between progressively narrowing limits, which, for the values of inductance occurring in actual coil construction, (namely from about 0, 10 to 0, henry) lie between about and 150 for time constants up to about 0.04: sec., and be tween about 50 and 110 for higher time constant values. As the magnetic field in the coil cores is very weak the so-called initial permeability of the material only is in question.
I have therefore made experiments in order to obtain material having a corn siderably smaller loss coefiicient mi in comparison with previous materials, while at the same time having an initial permea bility within the aforesaid limits. As the result of the experiments a material was discovered which consists of an alloy of iron and nickel, the iron being as free as possible from carbon and other impurities.
Iron-nickel alloys containing a suitable amount of carbon are well known in the art as nickel steels. They exhibit very considerable hysteresis losses. My experiments, have shown that if the carbon content is reduced to about 0.09 to 0.06%, the addition of nickel effects a considerable reduct tion in the hysteresis ltlspts of the iron, without at the same time increasing the initial permeabilityas occurs to example with the known iron-silicon alloys used tor transformer and dynamo plates. ltloreover the initial permeability can be reduced to any desired extent by increasing the proportion o'l nickel and can therefore be varied within the aforesaid limits. Since the added nickle also considerably lowers the conductivity of the iron, the eddy-current losses are also reduced.
For example, I have made a nickel-iron alloy consisting of practically pure iron with about 8% of nickel. The coetlicient of loss ow of this alloy is less than one third that of pure iron. The initial permeability is about 135. Self-induction coils made of this alloy having an inductance of 0.15 henry and a time constant of 0.04: seconds with a current of 0.5 milliampere at- 800 periods weigh only about. kilograms, whereas the selfinduction coils at the same elec rical constants hitherto used in the artweigh 10.5 kilograms.
The drawing accompanying and forming part of this specification illustrates in sectional elevation a coil embodying the present invention. In the drawing, a indicates the core formed in any well-known manner from a nickel-iron bar, Z) designates the insulating jacket extending around the core, and 0 designates the wire coil.
It is immaterial as regards the invention, how then aterial is subdivided for constructing the magnetization core, i. 0., whether it is used in the form of discs, strips, wire or powder. The advantage of using this material for loading coils can likewise be obtained when it is used for all magnetism tion cores in whi h it is desirable to combine the smallest possible weight with the highest possible time constants or with the smallest possible losses.
What I claim is An improved selt-induction coil comprising a magnetization core composed of an iron nickel alloy having 8 to 20 per cent nickel content and a carbon content of .06 to .09 per cent, in. combination with an insulating jacket and a surrounding wire coil,
In testimony whereol I have signed my name to this specification.
EUGEN SCHU'QEE.
US465251A 1921-04-28 1921-04-28 Self-induction coil Expired - Lifetime US1568422A (en)

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Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2548199A (en) * 1946-12-20 1951-04-10 Western Electric Co Loading coil

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2548199A (en) * 1946-12-20 1951-04-10 Western Electric Co Loading coil

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