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Driveability
Corner
Volume 3 Number 3
Vehicle:
’93
Ford T-Bird 3.8LSC
Ignition: EI Low Data Rate
Odometer: 89,600 miles
Customer complaint: “Check Engine Light
on, runs rough.”
Every
time I work on one of these 3.8L SC (Super Coupe) T-bird’s,
I know there will be bloodshed as it has to be one of the
tightest packages around due to the low hood line of this
car, coupled with a blower under the hood.
With
that said, my first step was to see how the thing ran. KOER
at idle, it actually ran OK, but under load it had a dead
miss. A DTC 217 was set which is a Coil 3 circuit failure.
This DTC is obviously related to this driveability problem.
A little
ignition background for this vehicle is in order. Ford calls
this system a Low Data Rate System (LDR) because the crankshaft
position sensor (CKP) generates only 3 signals per crank revolution
which does not offer a great deal of detail in comparison
to High Data Rate Systems (HDR) which generate 35 signals
per revolution.
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The
CKP is a 4-wire sensor: B+, ground, signal to the Ignition
Control Module (ICM),
and signal to the PCM. See figure
1 for the wiring diagram. The CKP signal
sent to the ICM is for ignition control and the signal
that is sent to the PCM is an RPM reference. A Camshaft
Position Sensor (CMP) or Cylinder ID (CID) is used on
this system for starting and sequential fuel injection.
It is also a 4-wire sensor similar to the CKP as it
generates 2 signals. One CMP signal is sent to the
ICM for coil firing sequence and one is sent to the
PCM for sequential injection.
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 The
secondary ignition is pretty straightforward, as it’s a waste
spark ignition system utilizing 1 coil for 2 cylinders for
a total of 3 coils. See figure
2.
OK, back
to the ‘Bird. I looked up the flow chart for the DTC 217
in the shop manual and to be brutally honest, it was terrible.
Lots of “connect special tool such and such” and “check resistance
of this and that”. No thanks. Give me a solid system operation
and a good wiring diagram and I’m off to the races! Ford
can throw away the flow chart for this DTC as far as I’m concerned…
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Based
on the DTC that set, there is a primary coil circuit
failure. What’s involved in the primary circuit?
An ICM which drives the coil on and off, the coil primary
windings and the related wiring. That’s about it.
With that said, I connected my low amp current probe
to the coil B+ feed at the coil pack and saw this.
Each coil “ramp” indicates current flow through a coil
primary circuit. Looking at this waveform, it’s pretty
obvious that a coil event or ramp is missing. OK, I’m
into this thing about 4 minutes and look what I already
know. Next, I connected channel 2 from the scope to
the coil driver circuit for coil 3, which is pin 9 at
the ICM. This
is what I saw.
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I
have a question for you. Based on figure 4, how’s the wiring
from the coil to the ICM? If you said good, pat yourself
on the back ‘cause you’re the man! Why? If you look back
at figure
2, you’ll notice that if I have B+ at the
ICM pin 9 (which I did), then the wiring MUST be good to
the coil, through the primary windings and all the
way to the ICM. Do I need to check resistance from
the coil to the ICM driver circuit? I don’t think so.
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Then
what’s the problem? It has to be the ICM because it’s
not driving the coil primary to ground like it should.
If you look back at figure
4, you’ll see that the driver circuit
voltage is staying “high” at open circuit voltage.
The fix? A new ICM. Figure
5 is the waveform after the ICM was
replaced. Note how the ICM is now properly driving
the coil primary on and off.
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Look for
more articles in the coming weeks!
Pete Vernazza
Advanced
Engine Performance Instructor
petev@attbi.com
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