A simple magneto (an electrical generator using permanent magnets) is able to produce relatively low voltage electricity, however it is unable to produce the high voltages required by a spark plug as used in most modern engines (aside from diesel engines).[2] An ignition magneto also includes an electrical transformer,[2] which converts the electricity to a higher voltage (with the trade-off being a corresponding reduction in the output current).[2]
As the points begin to open, point spacing is initially such that the voltage across the primary coil would arc across the points. A capacitor is placed across the points which absorbs the energy stored in the leakage inductance of the primary coil, and slows the rise time of the primary winding voltage to allow the points to open fully.[3]
A second coil, with many more turns than the primary, is wound on the same iron core to form an electrical transformer. The ratio of turns in the secondary winding to the number of turns in the primary winding, is called the turns ratio. Voltage across the primary coil results in a proportional voltage being induced across the secondary winding of the coil. The turns ratio between the primary and secondary coil is selected so that the voltage across the secondary reaches a very high value, enough to arc across the gap of the spark plug. As the voltage of the primary winding rises to several hundred volts,[3][4] the voltage on the secondary winding rises to several tens of thousands of volts, since the secondary winding typically has 100 times as many turns as the primary winding.[3]
Impulse coupling, induction vibrator, and booster coiledit
(Left) In a vibrator coil, points open and close rapidly, creating pulsating DC, or interrupted battery current. Electrical current flows from the battery through R1, vibrator points V1, and coil L2. The energized coil L2 opens vibrator points V1, interrupting the current flow through L2. The magnetic field about L2 collapses, and vibrator points V1 close again. Once more, current flows through L2, and again V1 vibrator points open. This process is repeated continuously, creating a "shower of sparks." (Right) Booster coil components. The booster coil is separate from the magneto and can generate a series of sparks on its own. Current flow through the primary coil sets up a magnetic field about the coil that attracts the movable contact point, breaking circuit is broken. The movable contact point then moves back to the stationary contact point via a spring. This sets up the current flow once again in a repetitive process.
Because the magneto has low voltage output at low speed, starting an engine is more difficult.[5] Therefore, some magnetos have an impulse coupling, a spring-like mechanical linkage between the engine and magneto drive shaft which "winds up" and "lets go" at the proper moment for spinning the magneto shaft. The impulse coupling uses a spring, a hub cam with flyweights, and a shell.[5] The hub of the magneto rotates while the drive shaft is held stationary, and the spring tension builds up. When the magneto is supposed to fire, the flyweights are released by the action of the body contacting the trigger ramp. This allows the spring to unwind giving the rotating magnet a rapid rotation and letting the magneto spin at such a speed to produce a spark.[5]
Historyedit
In the late 1890s, English engineer Frederick Richard Simms collaborated with the German engineer Robert Bosch, and his staff of Arnold Zähringer, Young Rall, and Gottlob Honold, in developing the first practical high-tension magneto. In 1900, the Bosch magneto ignition was used in the Gottlieb Daimler engines on the Zeppelin.[6][7]
The first car to use magneto ignition was the 1901 German Mercedes 35 hp racing car, followed by various cars produced by Benz, Mors, Turcat-Mery, and Nesseldorf.[8] Ignition magnetos were soon used on most cars, for both low voltage systems (which used secondary coils to fire the spark plugs) and high voltage magnetos (which fired the spark plug directly, similar to induction coil ignition).[8] Ignition magnetos were largely replaced by ignition coils once batteries became common in cars, since a battery-operated coil can provide a high-voltage spark even at low speeds, making starting easier.[9]
(Left) Aircraft dual ignition system with two individual magnetos, separate sets of wires, and spark plugs, increases reliability. (Right) Bosch magneto circuit diagram from 1911.
Referencesedit
Wikimedia Commons has media related to Magnetos (ignition).
^Bottone, Selimo Romeo (1907). Magnetos for Automobilists, how Made and how Used: A Handbook of Practical Instruction in the Manufacture and Adaptation of the Magneto to the Needs of the Motorist. C. Lockwood and son.
^ abcCauldwell, O. (1941). Aero Engines: for Pilots and Ground Engineers. Pitman. p. 88.
^ abc"The Aircraft Magneto". Continental Ignition Systems. 31 August 2011. from the original on 18 September 2015. Retrieved 21 June 2016.
^"Capacitors in Ignition Systems". www.smokstak.com. from the original on 9 July 2017. Retrieved 6 May 2018.
^ abcKroes, Michael (1995). Aircraft Powerplants. New York: Glencoe. p. 180.
^Heuss, Theodor (1994). Robert Bosch: His Life and Achievements. New York: Henry Holt and Company. pp. 102–107, 124–126. ISBN0805030670.
^ abGeorgano, G.N. (1985). Cars: Early and Vintage, 1886-1930. London: Grange-Universal.
^Hillier, V. A. W. (1996). Hillier's Fundamentals of Automotive Electronics. Nelson Thornes. p. 167. ISBN0-7487-2695-0.
January 01, 1970
ignition, magneto, ignition, magneto, also, called, high, tension, magneto, older, type, ignition, system, used, spark, ignition, engines, such, petrol, engines, uses, magneto, transformer, make, pulses, high, voltage, spark, plugs, older, term, high, tension,. An ignition magneto also called a high tension magneto is an older type of ignition system used in spark ignition engines such as petrol engines It uses a magneto and a transformer to make pulses of high voltage for the spark plugs The older term high tension means high voltage 1 Magneto components Impulse coupling components Contents 1 Design 1 1 Impulse coupling induction vibrator and booster coil 2 History 3 ReferencesDesign editA simple magneto an electrical generator using permanent magnets is able to produce relatively low voltage electricity however it is unable to produce the high voltages required by a spark plug as used in most modern engines aside from diesel engines 2 An ignition magneto also includes an electrical transformer 2 which converts the electricity to a higher voltage with the trade off being a corresponding reduction in the output current 2 As the points begin to open point spacing is initially such that the voltage across the primary coil would arc across the points A capacitor is placed across the points which absorbs the energy stored in the leakage inductance of the primary coil and slows the rise time of the primary winding voltage to allow the points to open fully 3 A second coil with many more turns than the primary is wound on the same iron core to form an electrical transformer The ratio of turns in the secondary winding to the number of turns in the primary winding is called the turns ratio Voltage across the primary coil results in a proportional voltage being induced across the secondary winding of the coil The turns ratio between the primary and secondary coil is selected so that the voltage across the secondary reaches a very high value enough to arc across the gap of the spark plug As the voltage of the primary winding rises to several hundred volts 3 4 the voltage on the secondary winding rises to several tens of thousands of volts since the secondary winding typically has 100 times as many turns as the primary winding 3 Impulse coupling induction vibrator and booster coil edit nbsp nbsp Left In a vibrator coil points open and close rapidly creating pulsating DC or interrupted battery current Electrical current flows from the battery through R1 vibrator points V1 and coil L2 The energized coil L2 opens vibrator points V1 interrupting the current flow through L2 The magnetic field about L2 collapses and vibrator points V1 close again Once more current flows through L2 and again V1 vibrator points open This process is repeated continuously creating a shower of sparks Right Booster coil components The booster coil is separate from the magneto and can generate a series of sparks on its own Current flow through the primary coil sets up a magnetic field about the coil that attracts the movable contact point breaking circuit is broken The movable contact point then moves back to the stationary contact point via a spring This sets up the current flow once again in a repetitive process Because the magneto has low voltage output at low speed starting an engine is more difficult 5 Therefore some magnetos have an impulse coupling a spring like mechanical linkage between the engine and magneto drive shaft which winds up and lets go at the proper moment for spinning the magneto shaft The impulse coupling uses a spring a hub cam with flyweights and a shell 5 The hub of the magneto rotates while the drive shaft is held stationary and the spring tension builds up When the magneto is supposed to fire the flyweights are released by the action of the body contacting the trigger ramp This allows the spring to unwind giving the rotating magnet a rapid rotation and letting the magneto spin at such a speed to produce a spark 5 History editIn the late 1890s English engineer Frederick Richard Simms collaborated with the German engineer Robert Bosch and his staff of Arnold Zahringer Young Rall and Gottlob Honold in developing the first practical high tension magneto In 1900 the Bosch magneto ignition was used in the Gottlieb Daimler engines on the Zeppelin 6 7 The first car to use magneto ignition was the 1901 German Mercedes 35 hp racing car followed by various cars produced by Benz Mors Turcat Mery and Nesseldorf 8 Ignition magnetos were soon used on most cars for both low voltage systems which used secondary coils to fire the spark plugs and high voltage magnetos which fired the spark plug directly similar to induction coil ignition 8 Ignition magnetos were largely replaced by ignition coils once batteries became common in cars since a battery operated coil can provide a high voltage spark even at low speeds making starting easier 9 nbsp nbsp Left Aircraft dual ignition system with two individual magnetos separate sets of wires and spark plugs increases reliability Right Bosch magneto circuit diagram from 1911 References edit nbsp Wikimedia Commons has media related to Magnetos ignition Bottone Selimo Romeo 1907 Magnetos for Automobilists how Made and how Used A Handbook of Practical Instruction in the Manufacture and Adaptation of the Magneto to the Needs of the Motorist C Lockwood and son a b c Cauldwell O 1941 Aero Engines for Pilots and Ground Engineers Pitman p 88 a b c The Aircraft Magneto Continental Ignition Systems 31 August 2011 Archived from the original on 18 September 2015 Retrieved 21 June 2016 Capacitors in Ignition Systems www smokstak com Archived from the original on 9 July 2017 Retrieved 6 May 2018 a b c Kroes Michael 1995 Aircraft Powerplants New York Glencoe p 180 Kohli P L 1993 Automotive Electrical Equipment Tata McGraw Hill ISBN 0 07 460216 0 Heuss Theodor 1994 Robert Bosch His Life and Achievements New York Henry Holt and Company pp 102 107 124 126 ISBN 0805030670 a b Georgano G N 1985 Cars Early and Vintage 1886 1930 London Grange Universal Hillier V A W 1996 Hillier s Fundamentals of Automotive Electronics Nelson Thornes p 167 ISBN 0 7487 2695 0 Retrieved from https en wikipedia org w index php title Ignition magneto amp oldid 1160353128, wikipedia, wiki, book, books, library,
