alternator troubleshooting with an oscilloscope
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Written by: Swagatam • Edited by: Lamar Stonecypher
Published Aug 23, 2010 • Related Guides: Electricity
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Home > Engineering > Electrical Engineering > Electronics Technology
How to Test an Alternator with an Oscilloscope
Alternator troubleshooting with an oscilloscope is definitely simpler and much accurate than any other means.
Here we diagnose the various typical waveform signatures produced by an oscilloscope and study what
indications they reveal through a step-wise analysis.
What is an Alternator?
Alternator troubleshooting with an oscilloscope, without a prior knowledge about an alternator's basic
operating principle, can become quite confusing and puzzling. The following explanations will briefly enlighten
you regarding alternators and their working concept, let's go through it.
An alternator is an electromechanical device that is able to convert externally applied mechanical energy into
an electrical energy through
electromagnetic induction, generated by a rotating movement of its shaft.
A modern alternator may be made up of the following essential elements:
A central rotating field winding assembly called the rotor.
A stationary induction winding assembly surrounding the rotor, called the stator.
A diode network or the rectifier.
A precision circuit unit called the voltage regulator is nowadays often included
within the outer aluminum enclosure of the alternators.
How an Alternator Operates
An alternator is probably the most essential part of every automobile and is most extensively used here. Its
functioning can be better understood by studying the various stages involved inside a typical vehicle alternator.
Let’s walk through its different stages of operation:
To initiate the alternator, some amount of power is derived from the battery which
is under charge and supplied to the rotor field winding via the voltage regulator.
The rotor armature instantly develops a strong magnetic field around it and
interacts with the stator assembly. The action forces the rotor to rotate. The
rotating rotor’s magnetic field around the stator induces a strong AC current in the
stator windings. This voltage is applied to the ignition chamber where it is
converted into a high voltage spark. The spark ignites the present fuel mixture to
create an explosion and start the engine. Since the engine is connected to the
rotor of the alternator through a pulley and belt mechanism, it takes hold of the
rotor rotation. The rotor now relieves the battery and starts rotating from engine power. After this, the
alternator’s stator voltage is solely used to charge the battery and power other electrical equipment.
A voltage regulator is specifically included to strictly monitor the charging level of the battery by correcting the
stator output current accordingly. The corrections are made by appropriately increasing or decreasing the
rotor field current.
For example, as long as the connected battery is not fully charged, the regulator maintains a higher current
level to the rotor field winding; this increases its electromagnetic effect over the stator winding, which in turn
delivers a higher amount of current to the battery. This process starts reversing as the battery gradually gets
fully charged.
Primarily, the stator may comprise of three sets of windings, each of these being positioned differently to
each other.
Normally the above windings exists in two types of configurations, namely in Wye and delta designs as shown
in the diagrams. The induced current from these windings result in a three phase output. Three phase output
helps in generating more voltage even at lower speeds, thus making the functions more efficient.
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When an alternator is intended to generate electricity from wind power, the
pulley-belt assembly of the rotor may be simply integrated to the turbine
mechanism and the above procedure replicated.
However, since the main idea here is to charge a connected battery most
efficiently, any malfunction in the above explained procedure may drastically
hamper the results. Also, since the entire operation involves many critical
electronic and mechanical stages, pin-pointing a particular snag may be pretty
difficult and can be properly located only with an oscilloscope.
The next section shows the various possible outcomes produced by an oscilloscope for different faults that
may possibly occur inside an alternator.
Image Courtesy : http://www.autoshop101.com/trainmodules/alternator/alt101.html
Using Oscilloscope for Troubleshooting Alternators
To test a running alternator over an oscilloscope, commence the procedure with
the following simple instructions:
Start the engine of your vehicle or the generator, now carefully unscrew the
battery from its clamps.
It is assumed that you know how to use an oscilloscope, otherwise go to -
http://www.doctronics.co.uk/scope.htm,
Broadly, you need to select the AC or the DC positions over the scope while
testing the various waveforms as indicated in the testing tips and keep it in parade
position preferably.
As shown in the adjoining figure, connect the scope's negative croc clip to the negative or the ground.
Connect a prod to the posive clip so that you may just need to touch this prod point to the terminal which was
previously attached to the battery positive. You may get one of the following readings as per the performance
of the alternator:
A typical oscilloscope waveform indicating a normal operating condition of an alternator is shown in the figure
below. The curve structure also shows that the alternator is running at the fast idle speed setting.
click to enlarge
A normal alternator should also produce a perfectly straight line response when monitored over an
oscilloscope in DC position. The figure below shows one such response. Here we can clearly witness the
proportionate increase in the voltage and the current with an increase in speed of the alternator.
click to enlarge
The next figure indicates the correct alternator waveform running at the slow idle mode. Here we see that the
waveforms are more uniform and rounded off than the fast idle mode. The curves are less sharp than the
previous waveform.
click to enlarge
As already discussed, a modern alternator may consist of a built-in rectifier module for the required
rectification process. If any one of the diodes involved in it becomes faulty (open), the efficiency of the
alternator may be hampered to a great extent and may affect the charging of the connected battery. The
graph below clearly portrays the resultant waveform for a diode failure. The curves also point towards an
open stator winding or windings. The patterns are typically during a slow idle speed of the alternator.
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Now if the speed is increased up to fast idle, the waveforms become more aggressive and prominent, as can
be seen in the bottom figure. During alternator troubleshooting with an oscilloscope, such waveforms may not
at all be a welcome sight and will certainly depict an impending malfunction.
click to enlarge
References
POPULAR MECHANICS,
http://www.autoshop101.com/trainmodules/alternator/alt101.html,
http://home.comcast.net/~loudgpz/GPZweb/GPZAltntrWaves/AlternatorWaveforms.html
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Alternator Troubleshooting with an Oscilloscope http://www.brighthub.com/engineering/electrical/articles/83694.aspx
3 of 4 12-09-2011 23:32
Alternator Troubleshooting with an Oscilloscope http://www.brighthub.com/engineering/electrical/articles/83694.aspx
4 of 4 12-09-2011 23:32