Audi
A8 Fuse Box Diagnostics
Introduction
Oscilloscopes are widely used in
diagnostics for the simple reason that they save time and money. This article
aims to give some advice to help you use your scope more effectively, so saving
more time and money.
When using an oscilloscope to test a
component, there is often a choice of either making a voltage measurement or
sensing the current waveform using a current clamp.
When making voltage measurements you
have to think about where you measure the signal, as the voltage can be
different in different parts of the same circuit. A simple rule is that when
measuring sensors (like cam and crank) you should measure as near to the ECU as
possible and when measuring actuators (such as injectors and throttle motors) you
should measure as close as possible to the actuator.
The theory behind this is that, when
looking at a sensor such as a crank sensor, what counts is the signal that the
ECU sees. The sensor might be functioning, but if the problem is within the
wiring loom the ECU may be getting no signal at all. Similarly, where the ECU
is outputting a signal to control an actuator (such as an injector), you should
ideally check the voltage signal near the component.
Whilst the above rule makes sense in
theory, it often falls down in practice. In many cases ease of access takes
priority, so you tend to grab a measurement where it’s quick and easy rather
than in the ideal location. Your instinct is always to save time and money.
While voltage can vary across a
series circuit, current does not, so you have more options of where to measure
(Figure 1). If testing an injector, for example, there is a temptation to test
the current at the injector even if this means spending time removing covers
and getting access to a wire.
Figure 1: Current and voltages in an
injector circuit
A better option is often to measure
current at the fuse box using a current clamp where you have easy access to
lots of circuits in one place (Figure 2). With a bit of experience you can
sometimes diagnose a car (or confirm a code from a scan tool) without even
opening the bonnet or hood.
There are however a few limitations
when measuring current from the fuse box. The first is that it will only work
for components that draw a significant current, which limits it to actuators
such as fuel pumps, injectors and ignition. It will not work for most sensors,
so these need voltage testing.
The second limitation is that, while
the label for a fuse might say ‘injectors’, it sometimes really means
‘injectors and a bunch of other stuff’. To minimise the chance of confusion due
to multiple circuits on the same fuse, we advise always starting with a
timebase of at least 20 ms/div across the screen. This ensures there is
enough time to observe a complete engine cycle at a normal idle speed.
Sometimes having more than one
circuit on a fuse can make understanding a signal more complicated, but on
other occasions it can actually help. Some Toyotas, for example, share a fuse
for injectors and ignition and this lets you see all injectors and ignition
coils fire just by probing one location. When you think this through, it makes
sense from the car owner’s point of view. There is no advantage for the
customer having separate fuses for the injectors and ignition coils: if either fuse
blows, the engine stops.
Let’s look at a few examples taken
from an Audi A8 with a 4.2L V8 petrol (gasoline) engine. As well as the
oscilloscope, all you need is a “low amps” probe and a fuse breakout lead. The
value of the fuse you remove to fit the breakout lead gives you a good clue as
to which range to set the scope to measure (if you removed a 20 A fuse,
set the scope to measure 20 A).
Figure 2: 60 A current clamp
being used with the fuse breakout lead.
Diagnostic assistant optional.
Diagnostic assistant optional.
Lambda
(oxygen) sensor heater circuit
Most modern lambda sensors have
heater circuits so that they can quickly get up to operating temperature. In
our experience, problems with the heater circuit are as common as those with
the sensor itself.
Figure 3: Lambda sensor waveform
Lambda sensors, due to their
location in the exhaust system, are often difficult to get to so it’s much
quicker (and more comfortable) to get at the signal from the comfort of the
passenger cabin.
The heater circuit in this example
is fairly typical, in that the ECU controls the amount of heating by rapidly
switching the heater on and off. The more time it’s on, the more heating we
get. Once the engine has been started, the peak current jumps to about 6 amps
and if you zoom in you can see that the heater is on more than it is off. After
30 seconds or so the sensor has warmed up and the current drops a bit, to about
4 A. This is because the heating element when warm has a higher resistance
than when cold (this is the same as a light bulb: when cold they draw more
current so often fail when first switched on). At the same time, the duty cycle
of the switching signal has changed and the heater is now switched off for more
time than it is on.
On this Audi, care is needed in
performing this test as the same fuse supplies two heater circuits. If you look
closely at the waveform you can see areas where only one of the heater circuits
is switched on giving a reading of about 2 A.
Injectors
The main advantage of testing
injectors from the fuse box is that you can see and compare all of them at
once: a real time saver on a V8 or V12.
Figure 4: Injector waveform
As we want to see at least one
complete engine cycle (two engine revolutions, so all injectors fire) we have
chosen a timebase of 20 ms/div. It’s fairly obvious that this vehicle is
only firing on seven cylinders, but be careful before leaping to any
conclusions. Often, if an ECU detects a misfire, it will disable the injector
of the offending cylinder to save the catalytic converter being damaged by the
unburnt fuel.
If you see a waveform like this, try
capturing another one just after the engine is switched on. The ECU will not
disable the injector until it has detected a misfire, which takes several
seconds. If you see all eight injectors but then one drops out, it’s very
likely that the ECU is disabling the cylinder. This would lead me to suspect
either an ignition or a mechanical issue. Fortunately, both of these problems
can also be tested using a current clamp as described later in the article. In
this case the vehicle did not have any real issues, so I unplugged the injector
to make the waveform more educational.
As well as a gross error such as an
injector not firing, it’s worth zooming in on each injector event to look for
more subtle issues by checking that the waveform from each one looks identical.
The waveform shown below is such a zoom: the dip in the waveform is the moment
that the solenoid (pintle) inside the injector moves and fuel begins to be
injected. If this is missing from one injector, it’s usually a sign that the
injector is either stuck closed or open. It’s also worth checking that this dip
happens in about the same place for each injector. If it’s early (usually a
weak spring in the injector) then too much fuel will be delivered; if it’s late
(sticky injector) then too little fuel is being delivered.
As well as the timing of the pintle
movement, check that current amplitude is roughly the same for each injector,
as if one injector is drawing more current the coil may be breaking down. Also
check that the time duration is about the same for each injector. If one
injector duration is longer or shorter than the rest then the ECU is trying to
compensate for a lack of power from that cylinder, so you need to find out why.
Ignition
Checking ignition on this car is
very similar to testing the injectors as it has one coil for each cylinder
(Coil on Plug). Again, as we can see all the cylinders firing on the same
waveform, it’s a case of comparing to look for any differences.
Figure 5: Ignition waveform
This vehicle seems to be one of
those where the fuse marked “ignition” is really for the “ignition coils and a
bunch of other stuff”. In this case it shows up as small (500 mA), rapid
(2 kHz) spikes in the current that give the waveform a noisy appearance.
The correct approach here is to
check the wiring diagram to see what is causing these spikes, but on this
occasion I decided I still had a clear enough view of each ignition event to
assume each ignition coil was firing. Within PicoScope software you can always
switch on the low–pass filter to remove such noise if it bothers you.
Fuel
pump
The fuel pump is another component
where access is usually difficult. Changing a fuel pump based on a wrong
diagnosis can really ruin your day. Again, if measuring from the fuse box,
start off at 20 ms/div then either zoom in or change the timebase so that
you see the waveform as shown.
Figure 6: Fuel pump current
We want to check two things on this
waveform. First is the average current, which in this case is about
5.5 amps. This is the value you would get if you used a multimeter to
measure the current. If you suspect problems with the fuel pump, many data
sources give typical currents for a given application. If the current is
outside the recommended range then, before condemning the pump, check the rest
of the fuel system. A blocked filter, for example, makes the pump work harder,
increasing current flow. A faulty fuel pressure regulator, on the other hand,
can reduce the current.
The current pulses are caused by the
individual sectors of the commutator in the pump’s electric motor. Most pumps
have 6 or 8 sectors. If one sector gives a significantly different waveform
(often dropping to near zero amps) then it’s bad news: the pump is on its way
out. This sign of impending doom is often impossible to spot just by measuring
the current using a meter, which does not respond quickly enough to the drop in
current.
Electronic
parking brake
Figure 7: Electronic parking brake
This waveform shows the brake first
being engaged. You will see spike in current before the motor starts moving
(over 20 amps in this case), then an area of fairly low current of about
1.6 A where the motor is taking up the slack space between the brake pad
and disk. The current then rapidly increases as the pad is pushed against the
disk, with a peak current of about 18 A.
When the brake is disengaged, the
process is reversed. You have the same spike in current followed by about 8
amps decaying away as the pad moves away from the disk. As with the ignition
example, this waveform seems to have similar spikes of current. In this case
the pulses are part of the correct operation of the EPB as about once a second
it performs a self–test.
This Audi has EPBs on both rear
wheels, so the best approach is to capture waveforms from both sides and then
compare. The reference waveform option in the PicoScope software is ideal for
this. You need to check that the currents for the engage and disengage
waveforms are similar and that the times are also similar. If the brake on one
side takes longer to engage than the other, it’s worth checking that the pads
are not worn unequally.
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