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Induction coil

October 27, 2023

This article is about the type of transformer that produces high-voltage pulses. For the more general electrical component, see Inductor. For the high-frequency heating coil, see induction heating. For the device in telephone sets, see hybrid coil.

An induction coil or "spark coil" (archaically known as an inductorium or Ruhmkorff coil[1] after Heinrich Rühmkorff) is a type of electrical transformer[2][3][4] used to produce high-voltage pulses from a low-voltage direct current (DC) supply.[1][5] To create the flux changes necessary to induce voltage in the secondary coil, the direct current in the primary coil is repeatedly interrupted by a vibrating mechanical contact called an interrupter.[1] Invented in 1836 by Nicholas Callan, with additional research by Charles Grafton Page and others,[1] the induction coil was the first type of transformer. It was widely used in x-ray machines,[1][6] spark-gap radio transmitters,[1][6] arc lighting and quack medical electrotherapy devices from the 1880s to the 1920s. Today its only common use is as the ignition coils in internal combustion engines and in physics education to demonstrate induction.

Antique induction coil used in schools, from around 1900, Bremerhaven, Germany
Induction coil showing construction, from 1920.

Construction and function Edit

 
Schematic diagram

An induction coil consists of two coils of insulated wire wound around a common iron core (M).[1][7] One coil, called the primary winding (P), is made from relatively few (tens or hundreds) turns of coarse wire.[7] The other coil, the secondary winding, (S) typically consists of up to a million turns of fine wire (up to 40 gauge).[8][1][7]

An electric current is passed through the primary, creating a magnetic field.[1][7] Because of the common core, most of the primary's magnetic field couples with the secondary winding.[citation needed] The primary behaves as an inductor, storing energy in the associated magnetic field. When the primary current is suddenly interrupted, the magnetic field rapidly collapses. This causes a high voltage pulse to be developed across the secondary terminals through electromagnetic induction. Because of the large number of turns in the secondary coil, the secondary voltage pulse is typically many thousands of volts. This voltage is often sufficient to cause an electric spark, to jump across an air gap (G) separating the secondary's output terminals. For this reason, induction coils were called spark coils.

An induction coil is traditionally characterised by the length of spark it can produce; a '4 inch' (10 cm) induction coil could produce a 4 inch spark. Until the development of the cathode ray oscilloscope, this was the most reliable measurement of peak voltage of such asymmetric waveforms. The relationship between spark length and voltage is linear within a wide range:

4 inches (10 cm) = 110kV ; 8 inches (20 cm) = 150kV ; 12 inches (30 cm) = 190kV ; 16 inches (41 cm) = 230kV[9]

Curves supplied by a 1984 reference agree closely with those values.[10]

Interrupter Edit

 
Without capacitor
 
With capacitor
Waveforms in an induction coil with output open (no spark). i1 (blue ) is the current in the coil's primary winding, v2 (red ) is the voltage across the secondary. Not to common scale; v2 is much larger in bottom drawing.[dubious discuss]

To operate the coil continually, the DC supply current must be repeatedly connected and disconnected to create the magnetic field changes needed for induction.[1] To do that, induction coils use a magnetically activated vibrating arm called an interrupter or break (A) to rapidly connect and break the current flowing into the primary coil.[1] The interrupter is mounted on the end of the coil next to the iron core. When the power is turned on, the increasing current in the primary coil produces an increasing magnetic field, the magnetic field attracts the interrupter's iron armature (A). After a time, the magnetic attraction overcomes the armature's spring force, and the armature begins to move. When the armature has moved far enough, the pair of contacts (K) in the primary circuit open and disconnect the primary current. Disconnecting the current causes the magnetic field to collapse and create the spark. Also, the collapsed field no longer attracts the armature, so the spring force accelerates the armature toward its initial position. A short time later the contacts reconnect, and the current starts building the magnetic field again. The whole process starts over and repeats many times per second. The secondary voltage v2 (red, left), is roughly proportional to the rate of change of primary current i1 (blue).

Opposite potentials are induced in the secondary when the interrupter 'breaks' the circuit and 'closes' the circuit. However, the current change in the primary is much more abrupt when the interrupter 'breaks'. When the contacts close, the current builds up slowly in the primary because the supply voltage has a limited ability to force current through the coil's inductance. In contrast, when the interrupter contacts open, the current falls to zero suddenly. So the pulse of voltage induced in the secondary at 'break' is much larger than the pulse induced at 'close', it is the 'break' that generates the coil's high voltage output.

Capacitor Edit

An arc forms at the interrupter contacts on break which has undesirable effects: the arc consumes energy stored in the magnetic field, reduces the output voltage, and damages the contacts.[11] To prevent this, a quenching capacitor (C) of 0.5 to 15 μF is connected across the primary coil to slow the rise in the voltage after a break. The capacitor and primary winding together form a tuned circuit, so on break, a damped sinusoidal wave of current flows in the primary and likewise induces a damped wave in the secondary. As a result, the high voltage output consists of a series of damped waves (left).[citation needed]

Construction details Edit

To prevent the high voltages generated in the coil from breaking down the thin insulation and arcing between the secondary wires, the secondary coil uses special construction so as to avoid having wires carrying large voltage differences lying next to each other. In one widely used technique, the secondary coil is wound in many thin flat pancake-shaped sections (called "pies"), connected in series.[12][1]

The primary coil is first wound on the iron core and insulated from the secondary with a thick paper or rubber coating.[1] Then each secondary subcoil is connected to the coil next to it and slid onto the iron core, insulated from adjoining coils with waxed cardboard disks. The voltage developed in each subcoil isn't large enough to jump between the wires in the subcoil.[1] Large voltages are only developed across many subcoils in series, which are too widely separated to arc over. To give the entire coil a final insulating coating, it is immersed in melted paraffin wax or rosin; the air evacuated to ensure there are no air bubbles left inside and the paraffin allowed to solidify, so the entire coil is encased in wax.

To prevent eddy currents, which cause energy losses, the iron core is made of a bundle of parallel iron wires, individually coated with shellac to insulate them electrically.[1] The eddy currents, which flow in loops in the core perpendicular to the magnetic axis, are blocked by the layers of insulation. The ends of the insulated primary coil often protruded several inches from either end of the secondary coil, to prevent arcs from the secondary to the primary or the core.

Mercury and electrolytic interrupters Edit

 
 
(left) 3-electrode Wehnelt interrupter used in high power coils. (right) Mercury turbine interrupter. The motor turns the toothed wheel while a stream of mercury is sprayed on the teeth. By adjusting the wheel up and down the duty cycle of the primary current can be changed.

Although modern induction coils used for educational purposes all use the vibrating arm 'hammer' type interrupter described above, these were inadequate for powering the large induction coils used in spark-gap radio transmitters and x-ray machines around the turn of the 20th century. In powerful coils the high primary current created arcs at the interrupter contacts which quickly destroyed the contacts.[1] Also, since each "break" produces a pulse of voltage from the coil, the more breaks per second the greater the power output. Hammer interrupters were not capable of interruption rates over 200 breaks per second and the ones used on powerful coils were limited to 20 – 40 breaks per second.

Therefore much research went into improving interrupters and improved designs were used in high power coils, with the hammer interrupters only used on small coils under 8" sparks.[13] Léon Foucault and others developed interrupters consisting of an oscillating needle dipping into and out of a container of mercury.[1] The mercury was covered with a layer of spirits which extinguished the arc quickly, causing faster switching. These were often driven by a separate electromagnet or motor,[1] which allowed the interruption rate and "dwell" time to be adjusted separately from the primary current.

The largest coils used either electrolytic or mercury turbine interrupters.[1] The electrolytic or Wehnelt interrupter, invented by Arthur Wehnelt in 1899, consisted of a short platinum needle anode immersed in an electrolyte of dilute sulfuric acid, with the other side of the circuit connected to a lead plate cathode.[1][14] When the primary current passed through it, hydrogen gas bubbles formed on the needle which repeatedly broke the circuit. This resulted in a primary current broken randomly at rates up to 2000 breaks per second. They were preferred for powering X-ray tubes. They produced a lot of heat and due to this the hydrogen could explode. Mercury turbine interrupters had a centrifugal pump which sprayed a stream of liquid mercury onto rotating metal contacts.[1] They could achieve interruption rates up to 10,000 breaks per second and were the most widely used type of interrupter in commercial wireless stations.[1][14]

History Edit

 
Early coil by William Sturgeon, 1837. The sawtooth zinc interrupter wheel (D) was turned by hand. The first coil to use a divided core of iron wires (F) to prevent eddy currents.
 
Early coil by Charles G. Page, 1838, had one of the first automatic interrupters. The cup was filled with mercury. The magnetic field attracted the iron piece on the arm (left), lifting the wire out of the cup, breaking the primary circuit.
 
Induction coil by Heinrich Ruhmkorff, 1850s. In addition to the hammer interrupter (right), it had a mercury interrupter by Fizeau (left) that could be adjusted to change the dwell time.
 
One of the largest coils ever constructed, built in 1877 by Alfred Apps for William Spottiswoode. Wound with 280 miles of wire, could produce a 42 in. (106 cm) spark, corresponding to roughly one million volts. Powered by 30 quart size liquid batteries and a separate interrupter (not shown).
 
The first induction coil, built by Nicholas Callan, 1836.

The induction coil was the first type of electrical transformer. During its development between 1836 and the 1860s, mostly by trial and error, researchers discovered many of the principles that governed all transformers, such as the proportionality between turns and output voltage and the use of a "divided" iron core to reduce eddy current losses.

Michael Faraday discovered the principle of induction, Faraday's induction law, in 1831 and did the first experiments with induction between coils of wire.[15] The induction coil was invented by the American physician Charles Grafton Page in 1836[16][17] and independently by Irish scientist and Catholic priest Nicholas Callan in the same year at the St. Patrick's College, Maynooth[1][18][19][20][21] and improved by William Sturgeon.[1] George Henry Bachhoffner[1] and Sturgeon (1837) independently discovered that a "divided" iron core of iron wires reduced power losses.[22] The early coils had hand cranked interrupters, invented by Callan and Antoine Philibert Masson (1837).[23][24][25] The automatic 'hammer' interrupter was invented by Rev. Prof. James William MacGauley (1838) of Dublin, Ireland,[16][26] Johann Philipp Wagner (1839), and Christian Ernst Neeff (1847).[1][27][28] Hippolyte Fizeau (1853) introduced the use of the quenching capacitor.[1][29][30] Heinrich Ruhmkorff generated higher voltages by greatly increasing the length of the secondary,[1] in some coils using 5 or 6 miles (10 km) of wire and produced sparks up to 16 inches. In the early 1850s, American inventor Edward Samuel Ritchie introduced the divided secondary construction to improve insulation.[31][32] Jonathan Nash Hearder worked on induction coils.[33][34][35][36][37] Callan's induction coil was named an IEEE Milestone in 2006.[38]

Induction coils were used to provide high voltage for early gas discharge and Crookes tubes and other high voltage research. They were also used to provide entertainment (lighting Geissler tubes, for example) and to drive small "shocking coils", Tesla coils and violet ray devices used in quack medicine. They were used by Hertz to demonstrate the existence of electromagnetic waves, as predicted by James Clerk Maxwell and by Lodge and Marconi in the first research into radio waves. Their largest industrial use was probably in early wireless telegraphy spark-gap radio transmitters and to power early cold cathode x-ray tubes from the 1890s to the 1920s, after which they were supplanted in both these applications by AC transformers and vacuum tubes. However their largest use was as the ignition coil or spark coil in the ignition system of internal combustion engines, where they are still used, although the interrupter contacts are now replaced by solid state switches. A smaller version is used to trigger the flash tubes used in cameras and strobe lights.

 
Induction coil (top) powering 1915 wall mounted x-ray unit, with electrolytic interrupter (bottom).
 
Vibrator ignition coil used in early automobiles such as the Ford Model T around 1910
 
Modern automobile ignition coil, the largest remaining use for induction coils

See also Edit

Footnotes Edit

  1. ^ a b c d e f g h i j k l m n o p q r s t u v w x y z aa ab Fleming, John Ambrose (1911). "Induction Coil" . In Chisholm, Hugh (ed.). Encyclopædia Britannica. Vol. 14 (11th ed.). Cambridge University Press. pp. 502–505.
  2. ^ "Annus Mirabilis". The New Scientist. London: Reed Business Information. 5 (19): 445. February 1959. Retrieved 20 November 2018.
  3. ^ Strickland, Jeffrey (2011). Weird Scientists: the Creators of Quantum Physics. Lulu. p. 98. ISBN 978-1-257-97624-9.
  4. ^ Waygood, Adrian (2016). Electrical Science for Technicians. Routledge. p. 162. ISBN 978-1-317-53491-4.
  5. ^ Collins, Archie F. (1908). The Design and Construction of Induction Coils. New York: Munn & Co. p. 98. p.98
  6. ^ a b Collins, 1908, p. iii
  7. ^ a b c d Collins, 1908, p. 16-19
  8. ^ Cyclopedia of Applied Electricity, American School of Correspondence, Chicago (1908), Electricity and Magnetism, 74. Induction coils.
  9. ^ Schall, K. (1914). Electro-medical Instruments and their Management. Schall & Son London.
  10. ^ E. Kuffel; W. S. Zaengl (1984). High Voltage Engineering. Pergamon Press. p. 374. ISBN 0-08-024212-X.
  11. ^ Schall, K. (1905). Electro-medical Instruments and their Management. Bemrose & Sons Ltd. Printers. pp. 78.
  12. ^ Schneider, Norman H. (1896). Ruhmkorff induction coils, their construction, operation and application. Spon & Chamberlain. pp. 10-14, 16.
  13. ^ Collins, 1908, p. 98
  14. ^ a b Moore, Arthur (1911). How to make a wireless set. Chicago: The Popular Mechanics Co. ISBN 978-1-4400-4874-6. The electrolytic interrupter consists of a vessel containing a solution of dilute sulphuric acid with two terminals immersed in this solution. The positive terminal or anode is made of platinum and should have a surface of about 3/16 in.[sic] The negative terminal or cathode is made of lead and should have an area of something like 1 sq. ft. When this interrupter is connected in series with the primary of an induction coil and a source of electromotive force of about 40 volts, the circuit will be interrupted, due to the formation and collapse of bubbles on the platinum electrode. Page 31 describes electrolytic interrupter, but does not identify as Wehnelt interrupter.
  15. ^ Faraday, Michael (1834). "Experimental Researches in Electricity. Seventh Series". Philosophical Transactions of the Royal Society of London. 124: 77–122. Bibcode:1834RSPT..124...77F. doi:10.1098/rstl.1834.0008. S2CID 116224057.
  16. ^ a b Page, Charles Grafton (1867). History of Induction: The American Claim to the Induction Coil and Its Electrostatic Developments. Washington, D.C.: Intelligencer Printing House. pp. 26–27, 57.
  17. ^ Czarnik, Stanley A. (March 1993). "The Classic Induction Coil" (PDF). Popular Electronics. 9 (3): 35–40. ISSN 1042-170X. Retrieved September 3, 2015., archived 2016-10-30 at the Wayback Machine
  18. ^ Callan, N. J. (December 1836). "On a new galvanic battery". Philosophical Magazine. 9 (3): 472–478. doi:10.1080/14786443608649044. Retrieved February 14, 2013.
  19. ^ Callan, N. J. A Description of an Electromagnetic Repeater in Sturgeon, Ed., William (1837). The Annals of Electricity, Magnetism, and Chemistry, Vol. 1. London: Sherwood, Gilbert, and Piper. pp. 229–230. and p.522 fig. 52
  20. ^ Fleming, John Ambrose (1896). The Alternate Current Transformer in Theory and Practice, Vol. 2. London: The Electrician Publishing Co. pp. 16–18.
  21. ^ McKeith, Niall. . National Science Museum. St. Patrick's College, Maynooth. Archived from the original on February 25, 2013. Retrieved February 14, 2013.
  22. ^ Fleming (1896) The Alternate Current Transformer in Theory and Practice, Vol. 2, p. 10-11
  23. ^ Masson, Antoine Philibert (1837). "Rapport sur plusieurs mémoires, relatifs à un mode particulier d'action des courants électriques (Report on several memoirs regarding a particular mode of action of electric currents)". Comptes Rendus. 4: 456–460. Retrieved February 14, 2013. On page 458, an interrupter consisting of a toothed wheel is described.
  24. ^ Masson, A. (1837). "De l'induction d'un courant sur lui-même (On the induction of a current in itself)". Annales de Chimie et de Physique. 66: 5–36. Retrieved February 14, 2013.
  25. ^ Masson, Antoine Philibert; Louis Breguet (1841). "Mémoire sur l'induction". Annales de Chimie et de Physique. 4 (3): 129–152. Retrieved February 14, 2013. On page 134, Masson describes the toothed wheels that functioned as an interrupter.
  26. ^ McGauley, J. W. (1838). "Electro-magnetic apparatus for the production of electricity of high intensity". Proceedings of the British Association for the Advancement of Science. 7: 25. presented at meeting of September 1837 in Liverpool, England
  27. ^ Neeff, Christian Ernst (1839). "Ueber einen neuen Magnetelektromotor (On a new electromagnetic motor)". Annalen der Physik und Chemie. 46: 104–127. Retrieved February 14, 2013.
  28. ^ Neeff, C. (1835). "Das Blitzrad, ein Apparat zu rasch abwechselnden galvanischen Schliessungen und Trennungen (The spark wheel, an apparatus for rapidly alternating closings and openings of galvanic circuits)". Annalen der Physik und Chemie. 36: 352–366. Retrieved February 14, 2013. Description of Neeff and Wagner's earlier toothed wheel interrupter
  29. ^ Fizeau, H. (1853). "Note sur les machines électriques inductives et sur un moyen facile d'accroître leurs effets" [Note on electric induction machines and on an easy way to increase their effects]. Comptes Rendus (in French). 36: 418–421. Retrieved February 14, 2013.
  30. ^ Severns, Rudy. (PDF). Design Resource Center. Switching Power Magazine. Archived from the original (PDF) on 2011-07-16. Retrieved 2008-05-16.
  31. ^ American Academy of Arts and Sciences, Proceedings of the American Academy of Arts and Sciences, Vol. XXIII, May 1895 - May 1896, Boston: University Press, John Wilson and Son (1896), pp. 359-360
  32. ^ Page, Charles G., History of Induction: The American Claim to the Induction Coil and Its Electrostatic Developments, Washington, D.C.: Intelligencer Printing House (1867), pp. 104-106
  33. ^ Fleming, J. A. (1891). "The Historical Development of the Induction Coil and Transformer". The Electrician. 26–27: V26:––417, V27: 211–213, 246–248, 300–302, 359–361, 433–435. at page 360.
  34. ^ "Hearder's induction coil". Journal of the Franklin Institute. 63 (3): 179–81. 1857. doi:10.1016/0016-0032(57)90712-3.
  35. ^ "The improved induction coil". Philosophical Magazine. Series 4. 13 (88): 471. 1857. doi:10.1080/14786445708642330.
  36. ^ "The improved induction coil". Philosophical Magazine. Series 4. 14 (93): 319–20. 1857. doi:10.1080/14786445708642396.
  37. ^ Hearder, Ian G. (September 2004). "Hearder, Jonathan Nash (1809–1876)". Oxford Dictionary of National Biography. Oxford University Press. Retrieved 7 April 2010.
  38. ^ "Milestones:Callan's Pioneering Contributions to Electrical Science and Technology, 1836". IEEE Global History Network. IEEE. Retrieved 26 July 2011.

Further reading Edit

  • Norrie, H. S., "Induction Coils: How to Make, Use, and Repair Them". Norman H. Schneider, 1907, New York. 4th edition.
  • Collins, Archie F. (1908). The Design and Construction of Induction Coils. New York: Munn & Co. p. 98.
  • Fleming, John Ambrose (1896). The Alternate Current Transformer in Theory and Practice, Vol.2. The Electrician Publishing Co. Has detailed history of invention of induction coil

External links Edit

  • Battery powered Driver circuit for Induction Coils
  • The Cathode Ray Tube site
  • Fleming, John Ambrose (1911). "Induction Coil" . In Chisholm, Hugh (ed.). Encyclopædia Britannica. Vol. 14 (11th ed.). Cambridge University Press. pp. 502–505.
  • Newman, F. H. (1921). "A New Form of Wehnelt Interrupter". Proceedings of the Royal Society A: Mathematical, Physical and Engineering Sciences. 99 (699): 324–30. Bibcode:1921RSPSA..99..324N. doi:10.1098/rspa.1921.0045. JSTOR 93959.
  • Relay Technical Information See section "Contact Protection – Counter EMF".
  • See figure 9 for actual discharge.

October 27, 2023
induction, coil, this, article, about, type, transformer, that, produces, high, voltage, pulses, more, general, electrical, component, inductor, high, frequency, heating, coil, induction, heating, device, telephone, sets, hybrid, coil, induction, coil, spark, . This article is about the type of transformer that produces high voltage pulses For the more general electrical component see Inductor For the high frequency heating coil see induction heating For the device in telephone sets see hybrid coil An induction coil or spark coil archaically known as an inductorium or Ruhmkorff coil 1 after Heinrich Ruhmkorff is a type of electrical transformer 2 3 4 used to produce high voltage pulses from a low voltage direct current DC supply 1 5 To create the flux changes necessary to induce voltage in the secondary coil the direct current in the primary coil is repeatedly interrupted by a vibrating mechanical contact called an interrupter 1 Invented in 1836 by Nicholas Callan with additional research by Charles Grafton Page and others 1 the induction coil was the first type of transformer It was widely used in x ray machines 1 6 spark gap radio transmitters 1 6 arc lighting and quack medical electrotherapy devices from the 1880s to the 1920s Today its only common use is as the ignition coils in internal combustion engines and in physics education to demonstrate induction Antique induction coil used in schools from around 1900 Bremerhaven GermanyInduction coil showing construction from 1920 Contents 1 Construction and function 1 1 Interrupter 1 2 Capacitor 1 3 Construction details 2 Mercury and electrolytic interrupters 3 History 4 See also 5 Footnotes 6 Further reading 7 External linksConstruction and function Edit nbsp Schematic diagramAn induction coil consists of two coils of insulated wire wound around a common iron core M 1 7 One coil called the primary winding P is made from relatively few tens or hundreds turns of coarse wire 7 The other coil the secondary winding S typically consists of up to a million turns of fine wire up to 40 gauge 8 1 7 An electric current is passed through the primary creating a magnetic field 1 7 Because of the common core most of the primary s magnetic field couples with the secondary winding citation needed The primary behaves as an inductor storing energy in the associated magnetic field When the primary current is suddenly interrupted the magnetic field rapidly collapses This causes a high voltage pulse to be developed across the secondary terminals through electromagnetic induction Because of the large number of turns in the secondary coil the secondary voltage pulse is typically many thousands of volts This voltage is often sufficient to cause an electric spark to jump across an air gap G separating the secondary s output terminals For this reason induction coils were called spark coils An induction coil is traditionally characterised by the length of spark it can produce a 4 inch 10 cm induction coil could produce a 4 inch spark Until the development of the cathode ray oscilloscope this was the most reliable measurement of peak voltage of such asymmetric waveforms The relationship between spark length and voltage is linear within a wide range 4 inches 10 cm 110kV 8 inches 20 cm 150kV 12 inches 30 cm 190kV 16 inches 41 cm 230kV 9 Curves supplied by a 1984 reference agree closely with those values 10 Interrupter Edit nbsp Without capacitor nbsp With capacitorWaveforms in an induction coil with output open no spark i1 blue is the current in the coil s primary winding v2 red is the voltage across the secondary Not to common scale v2 is much larger in bottom drawing dubious discuss To operate the coil continually the DC supply current must be repeatedly connected and disconnected to create the magnetic field changes needed for induction 1 To do that induction coils use a magnetically activated vibrating arm called an interrupter or break A to rapidly connect and break the current flowing into the primary coil 1 The interrupter is mounted on the end of the coil next to the iron core When the power is turned on the increasing current in the primary coil produces an increasing magnetic field the magnetic field attracts the interrupter s iron armature A After a time the magnetic attraction overcomes the armature s spring force and the armature begins to move When the armature has moved far enough the pair of contacts K in the primary circuit open and disconnect the primary current Disconnecting the current causes the magnetic field to collapse and create the spark Also the collapsed field no longer attracts the armature so the spring force accelerates the armature toward its initial position A short time later the contacts reconnect and the current starts building the magnetic field again The whole process starts over and repeats many times per second The secondary voltage v2 red left is roughly proportional to the rate of change of primary current i1 blue Opposite potentials are induced in the secondary when the interrupter breaks the circuit and closes the circuit However the current change in the primary is much more abrupt when the interrupter breaks When the contacts close the current builds up slowly in the primary because the supply voltage has a limited ability to force current through the coil s inductance In contrast when the interrupter contacts open the current falls to zero suddenly So the pulse of voltage induced in the secondary at break is much larger than the pulse induced at close it is the break that generates the coil s high voltage output Capacitor Edit An arc forms at the interrupter contacts on break which has undesirable effects the arc consumes energy stored in the magnetic field reduces the output voltage and damages the contacts 11 To prevent this a quenching capacitor C of 0 5 to 15 mF is connected across the primary coil to slow the rise in the voltage after a break The capacitor and primary winding together form a tuned circuit so on break a damped sinusoidal wave of current flows in the primary and likewise induces a damped wave in the secondary As a result the high voltage output consists of a series of damped waves left citation needed Construction details Edit To prevent the high voltages generated in the coil from breaking down the thin insulation and arcing between the secondary wires the secondary coil uses special construction so as to avoid having wires carrying large voltage differences lying next to each other In one widely used technique the secondary coil is wound in many thin flat pancake shaped sections called pies connected in series 12 1 The primary coil is first wound on the iron core and insulated from the secondary with a thick paper or rubber coating 1 Then each secondary subcoil is connected to the coil next to it and slid onto the iron core insulated from adjoining coils with waxed cardboard disks The voltage developed in each subcoil isn t large enough to jump between the wires in the subcoil 1 Large voltages are only developed across many subcoils in series which are too widely separated to arc over To give the entire coil a final insulating coating it is immersed in melted paraffin wax or rosin the air evacuated to ensure there are no air bubbles left inside and the paraffin allowed to solidify so the entire coil is encased in wax To prevent eddy currents which cause energy losses the iron core is made of a bundle of parallel iron wires individually coated with shellac to insulate them electrically 1 The eddy currents which flow in loops in the core perpendicular to the magnetic axis are blocked by the layers of insulation The ends of the insulated primary coil often protruded several inches from either end of the secondary coil to prevent arcs from the secondary to the primary or the core Mercury and electrolytic interrupters Edit nbsp nbsp left 3 electrode Wehnelt interrupter used in high power coils right Mercury turbine interrupter The motor turns the toothed wheel while a stream of mercury is sprayed on the teeth By adjusting the wheel up and down the duty cycle of the primary current can be changed Although modern induction coils used for educational purposes all use the vibrating arm hammer type interrupter described above these were inadequate for powering the large induction coils used in spark gap radio transmitters and x ray machines around the turn of the 20th century In powerful coils the high primary current created arcs at the interrupter contacts which quickly destroyed the contacts 1 Also since each break produces a pulse of voltage from the coil the more breaks per second the greater the power output Hammer interrupters were not capable of interruption rates over 200 breaks per second and the ones used on powerful coils were limited to 20 40 breaks per second Therefore much research went into improving interrupters and improved designs were used in high power coils with the hammer interrupters only used on small coils under 8 sparks 13 Leon Foucault and others developed interrupters consisting of an oscillating needle dipping into and out of a container of mercury 1 The mercury was covered with a layer of spirits which extinguished the arc quickly causing faster switching These were often driven by a separate electromagnet or motor 1 which allowed the interruption rate and dwell time to be adjusted separately from the primary current The largest coils used either electrolytic or mercury turbine interrupters 1 The electrolytic or Wehnelt interrupter invented by Arthur Wehnelt in 1899 consisted of a short platinum needle anode immersed in an electrolyte of dilute sulfuric acid with the other side of the circuit connected to a lead plate cathode 1 14 When the primary current passed through it hydrogen gas bubbles formed on the needle which repeatedly broke the circuit This resulted in a primary current broken randomly at rates up to 2000 breaks per second They were preferred for powering X ray tubes They produced a lot of heat and due to this the hydrogen could explode Mercury turbine interrupters had a centrifugal pump which sprayed a stream of liquid mercury onto rotating metal contacts 1 They could achieve interruption rates up to 10 000 breaks per second and were the most widely used type of interrupter in commercial wireless stations 1 14 History Edit nbsp Early coil by William Sturgeon 1837 The sawtooth zinc interrupter wheel D was turned by hand The first coil to use a divided core of iron wires F to prevent eddy currents nbsp Early coil by Charles G Page 1838 had one of the first automatic interrupters The cup was filled with mercury The magnetic field attracted the iron piece on the arm left lifting the wire out of the cup breaking the primary circuit nbsp Induction coil by Heinrich Ruhmkorff 1850s In addition to the hammer interrupter right it had a mercury interrupter by Fizeau left that could be adjusted to change the dwell time nbsp One of the largest coils ever constructed built in 1877 by Alfred Apps for William Spottiswoode Wound with 280 miles of wire could produce a 42 in 106 cm spark corresponding to roughly one million volts Powered by 30 quart size liquid batteries and a separate interrupter not shown nbsp The first induction coil built by Nicholas Callan 1836 The induction coil was the first type of electrical transformer During its development between 1836 and the 1860s mostly by trial and error researchers discovered many of the principles that governed all transformers such as the proportionality between turns and output voltage and the use of a divided iron core to reduce eddy current losses Michael Faraday discovered the principle of induction Faraday s induction law in 1831 and did the first experiments with induction between coils of wire 15 The induction coil was invented by the American physician Charles Grafton Page in 1836 16 17 and independently by Irish scientist and Catholic priest Nicholas Callan in the same year at the St Patrick s College Maynooth 1 18 19 20 21 and improved by William Sturgeon 1 George Henry Bachhoffner 1 and Sturgeon 1837 independently discovered that a divided iron core of iron wires reduced power losses 22 The early coils had hand cranked interrupters invented by Callan and Antoine Philibert Masson 1837 23 24 25 The automatic hammer interrupter was invented by Rev Prof James William MacGauley 1838 of Dublin Ireland 16 26 Johann Philipp Wagner 1839 and Christian Ernst Neeff 1847 1 27 28 Hippolyte Fizeau 1853 introduced the use of the quenching capacitor 1 29 30 Heinrich Ruhmkorff generated higher voltages by greatly increasing the length of the secondary 1 in some coils using 5 or 6 miles 10 km of wire and produced sparks up to 16 inches In the early 1850s American inventor Edward Samuel Ritchie introduced the divided secondary construction to improve insulation 31 32 Jonathan Nash Hearder worked on induction coils 33 34 35 36 37 Callan s induction coil was named an IEEE Milestone in 2006 38 Induction coils were used to provide high voltage for early gas discharge and Crookes tubes and other high voltage research They were also used to provide entertainment lighting Geissler tubes for example and to drive small shocking coils Tesla coils and violet ray devices used in quack medicine They were used by Hertz to demonstrate the existence of electromagnetic waves as predicted by James Clerk Maxwell and by Lodge and Marconi in the first research into radio waves Their largest industrial use was probably in early wireless telegraphy spark gap radio transmitters and to power early cold cathode x ray tubes from the 1890s to the 1920s after which they were supplanted in both these applications by AC transformers and vacuum tubes However their largest use was as the ignition coil or spark coil in the ignition system of internal combustion engines where they are still used although the interrupter contacts are now replaced by solid state switches A smaller version is used to trigger the flash tubes used in cameras and strobe lights nbsp Induction coil top powering 1915 wall mounted x ray unit with electrolytic interrupter bottom nbsp Vibrator ignition coil used in early automobiles such as the Ford Model T around 1910 nbsp Modern automobile ignition coil the largest remaining use for induction coilsSee also EditIgnition coil Trembler coil Spark gap transmitter Transformer Tesla coil Faraday s law of induction Ignition system Inductor Magnetic field Nicholas CallanFootnotes Edit a b c d e f g h i j k l m n o p q r s t u v w x y z aa ab Fleming John Ambrose 1911 Induction Coil In Chisholm Hugh ed Encyclopaedia Britannica Vol 14 11th ed Cambridge University Press pp 502 505 Annus Mirabilis The New Scientist London Reed Business Information 5 19 445 February 1959 Retrieved 20 November 2018 Strickland Jeffrey 2011 Weird Scientists the Creators of Quantum Physics Lulu p 98 ISBN 978 1 257 97624 9 Waygood Adrian 2016 Electrical Science for Technicians Routledge p 162 ISBN 978 1 317 53491 4 Collins Archie F 1908 The Design and Construction of Induction Coils New York Munn amp Co p 98 p 98 a b Collins 1908 p iii a b c d Collins 1908 p 16 19 Cyclopedia of Applied Electricity American School of Correspondence Chicago 1908 Electricity and Magnetism 74 Induction coils Schall K 1914 Electro medical Instruments and their Management Schall amp Son London E Kuffel W S Zaengl 1984 High Voltage Engineering Pergamon Press p 374 ISBN 0 08 024212 X Schall K 1905 Electro medical Instruments and their Management Bemrose amp Sons Ltd Printers pp 78 Schneider Norman H 1896 Ruhmkorff induction coils their construction operation and application Spon amp Chamberlain pp 10 14 16 Collins 1908 p 98 a b Moore Arthur 1911 How to make a wireless set Chicago The Popular Mechanics Co ISBN 978 1 4400 4874 6 The electrolytic interrupter consists of a vessel containing a solution of dilute sulphuric acid with two terminals immersed in this solution The positive terminal or anode is made of platinum and should have a surface of about 3 16 in sic The negative terminal or cathode is made of lead and should have an area of something like 1 sq ft When this interrupter is connected in series with the primary of an induction coil and a source of electromotive force of about 40 volts the circuit will be interrupted due to the formation and collapse of bubbles on the platinum electrode Page 31 describes electrolytic interrupter but does not identify as Wehnelt interrupter Faraday Michael 1834 Experimental Researches in Electricity Seventh Series Philosophical Transactions of the Royal Society of London 124 77 122 Bibcode 1834RSPT 124 77F doi 10 1098 rstl 1834 0008 S2CID 116224057 a b Page Charles Grafton 1867 History of Induction The American Claim to the Induction Coil and Its Electrostatic Developments Washington D C Intelligencer Printing House pp 26 27 57 Czarnik Stanley A March 1993 The Classic Induction Coil PDF Popular Electronics 9 3 35 40 ISSN 1042 170X Retrieved September 3 2015 archived Archived 2016 10 30 at the Wayback Machine Callan N J December 1836 On a new galvanic battery Philosophical Magazine 9 3 472 478 doi 10 1080 14786443608649044 Retrieved February 14 2013 Callan N J A Description of an Electromagnetic Repeater in Sturgeon Ed William 1837 The Annals of Electricity Magnetism and Chemistry Vol 1 London Sherwood Gilbert and Piper pp 229 230 and p 522 fig 52 Fleming John Ambrose 1896 The Alternate Current Transformer in Theory and Practice Vol 2 London The Electrician Publishing Co pp 16 18 McKeith Niall Reverend Professor Nicholas Callan National Science Museum St Patrick s College Maynooth Archived from the original on February 25 2013 Retrieved February 14 2013 Fleming 1896 The Alternate Current Transformer in Theory and Practice Vol 2 p 10 11 Masson Antoine Philibert 1837 Rapport sur plusieurs memoires relatifs a un mode particulier d action des courants electriques Report on several memoirs regarding a particular mode of action of electric currents Comptes Rendus 4 456 460 Retrieved February 14 2013 On page 458 an interrupter consisting of a toothed wheel is described Masson A 1837 De l induction d un courant sur lui meme On the induction of a current in itself Annales de Chimie et de Physique 66 5 36 Retrieved February 14 2013 Masson Antoine Philibert Louis Breguet 1841 Memoire sur l induction Annales de Chimie et de Physique 4 3 129 152 Retrieved February 14 2013 On page 134 Masson describes the toothed wheels that functioned as an interrupter McGauley J W 1838 Electro magnetic apparatus for the production of electricity of high intensity Proceedings of the British Association for the Advancement of Science 7 25 presented at meeting of September 1837 in Liverpool England Neeff Christian Ernst 1839 Ueber einen neuen Magnetelektromotor On a new electromagnetic motor Annalen der Physik und Chemie 46 104 127 Retrieved February 14 2013 Neeff C 1835 Das Blitzrad ein Apparat zu rasch abwechselnden galvanischen Schliessungen und Trennungen The spark wheel an apparatus for rapidly alternating closings and openings of galvanic circuits Annalen der Physik und Chemie 36 352 366 Retrieved February 14 2013 Description of Neeff and Wagner s earlier toothed wheel interrupter Fizeau H 1853 Note sur les machines electriques inductives et sur un moyen facile d accroitre leurs effets Note on electric induction machines and on an easy way to increase their effects Comptes Rendus in French 36 418 421 Retrieved February 14 2013 Severns Rudy History of soft switching Part 2 PDF Design Resource Center Switching Power Magazine Archived from the original PDF on 2011 07 16 Retrieved 2008 05 16 American Academy of Arts and Sciences Proceedings of the American Academy of Arts and Sciences Vol XXIII May 1895 May 1896 Boston University Press John Wilson and Son 1896 pp 359 360 Page Charles G History of Induction The American Claim to the Induction Coil and Its Electrostatic Developments Washington D C Intelligencer Printing House 1867 pp 104 106 Fleming J A 1891 The Historical Development of the Induction Coil and Transformer The Electrician 26 27 V26 417 V27 211 213 246 248 300 302 359 361 433 435 at page 360 Hearder s induction coil Journal of the Franklin Institute 63 3 179 81 1857 doi 10 1016 0016 0032 57 90712 3 The improved induction coil Philosophical Magazine Series 4 13 88 471 1857 doi 10 1080 14786445708642330 The improved induction coil Philosophical Magazine Series 4 14 93 319 20 1857 doi 10 1080 14786445708642396 Hearder Ian G September 2004 Hearder Jonathan Nash 1809 1876 Oxford Dictionary of National Biography Oxford University Press Retrieved 7 April 2010 Milestones Callan s Pioneering Contributions to Electrical Science and Technology 1836 IEEE Global History Network IEEE Retrieved 26 July 2011 Further reading EditNorrie H S Induction Coils How to Make Use and Repair Them Norman H Schneider 1907 New York 4th edition Collins Archie F 1908 The Design and Construction of Induction Coils New York Munn amp Co p 98 Fleming John Ambrose 1896 The Alternate Current Transformer in Theory and Practice Vol 2 The Electrician Publishing Co Has detailed history of invention of induction coilExternal links EditBattery powered Driver circuit for Induction Coils The Cathode Ray Tube site Fleming John Ambrose 1911 Induction Coil In Chisholm Hugh ed Encyclopaedia Britannica Vol 14 11th ed Cambridge University Press pp 502 505 Newman F H 1921 A New Form of Wehnelt Interrupter Proceedings of the Royal Society A Mathematical Physical and Engineering Sciences 99 699 324 30 Bibcode 1921RSPSA 99 324N doi 10 1098 rspa 1921 0045 JSTOR 93959 Relay Technical Information See section Contact Protection Counter EMF Capacitive Discharge Ignition vs Magnetic Discharge Ignition Ignition System Options for the TR4A See figure 9 for actual discharge Retrieved from https en wikipedia org w index php title Induction coil amp oldid 1177091811, wikipedia, wiki, book, books, library,

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