Chrysler RG Voyager. Manual — part 530
assist the field technician in repairing vehicle prob-
lems by the quickest means.
3.2
FUNCTIONAL OPERATION
3.2.1
FUEL CONTROL
The PCM controls the air/fuel ratio of the engine
by varying fuel injector on time. Mass air flow is
calculated using the speed density method using
enigne speed, manifold absolute pressure, and air
temperature change.
Different fuel calculation strategies are used de-
pending on the operational state of the engine.
During crank mode, a longer pulse width fuel pulse
is delivered followed by fuel pulses determined by a
crank time strategy. Cold engine operation is deter-
mined via an open loop strategy until the O2
sensors have reached operating temperature. At
this point, the strategy enters a closed loop mode
where fuel requirements are based upon the state of
the O2 sensors, engine speed, MAP, throttle posi-
tion, air temperature, battery voltage, and coolant
temperature.
3.2.2
ON-BOARD DIAGNOSTICS
The PCM has been programmed to monitor many
different circuits of the fuel injection system. This
monitoring is called on-board diagnosis.
Certain criteria, or arming conditions, must be
met for a trouble code to be entered into the PCM
memory. The criteria may be a range of: engine rpm,
engine temperature, and/or input voltage to the
PCM. If a problem is sensed with a monitored
circuit, and all of the criteria or arming conditions
are met, then a trouble code will be stored in the
PCM.
It is possible that a trouble code for a monitored
circuit may not be entered into the PCM memory
even though a malfunction has occurred. This may
happen because one of the trouble code criteria have
not been met.
The PCM compares input signal voltages from
each input device with specifications (the estab-
lished high and low limits of the range) that are
programmed into it for that device. If the input
voltage is not within specifications and other trou-
ble code criteria are met, a trouble code will be
stored in the PCM memory.
The On Board Diagnostics have evolved to the
second Generation of Diagnostics referred to as
OBDII/EOBD. These OBDII/EOBD Diagnostics
control the functions necessary to meet the require-
ments of California OBDII, Federal OBD regulation
and European regulation. These requirements spec-
ify the inclusion of a Malfunction Indicator Light
(MIL) located on the instrument panel. The purpose
of the MIL is to inform the vehicle operator in the
event of a malfunction of any emission system or
component.
MIL Lamp Strategy
I/M Readiness OK to test = Key On Engine OFF
– MIL Lamp will remain on until the vehicle is
started or Ignition is turned off.
I/M not ready for testing = Key On Engine OFF
– MIL Lamp on solid for (15) seconds then MIL
Lamp will flash on/off for (5) seconds then it will
remain on until the vehicle is started or the Ignition
is turned off.
2
GENERAL INFORMATION
OBD II/EOBD MONITOR INFORMATION
Comprehensive
Major Monitors
Major Monitors
Components
Non Fuel Control
Fuel Control
Monitor
& Non Misfire
& Misfire
Run constantly
Run Once Per Trip
Run Constantly
Includes All Engine Hardware
Monitors Entire Emission
Monitors Entire System
- Sensors, Switches,
System
Solenoids, etc.
One Trip Faults - Turns On
Two Trip Faults - Turns On
Two Trip Faults - Turns On
The MIL and Sets DTC After
The MIL and Sets DTC After
The MIL and Sets DTC After
One Failure
Two Consecutive Failures
Two Consecutive Failures
Priority 3
Priority 1 or 3
Priority 2 or 4
All Checked For Continuity
Done Stop Testing = Yes
Fuel Control Monitor
Open
Monitors Fuel Control
Short To Ground
Oxygen Sensor Heater
System For:
Short To Voltage
Oxygen Sensor Response
Fuel System Lean
Fuel System Rich
Inputs Checked For
Requires 3 Consecutive
Rationality
Catalytic Converter
Fuel System Good Trips
To
Efficiency Except EWMA
Extinguish The MIL
Outputs Checked For
- up to 6 tests per trip
Functionality
and a one trip fault
EGR System
Misfire Monitor
Evaporative Emission
Monitors For Engine Misfire
System
at:
1000 RPM Counter
(Type B)
**200 RPM Counter
(Type A)
Requires 3 Consecutive
Requires 3 Consecutive
Requires 3 Consecutive
Global/Alternate Good Trips
Global Good Trips
Misfire Good Trips
to Extinguish the MIL*
to Extinguish the MIL*
To Extinguish the MIL
*40 Warm Up Cycles are required to erase
**Type A misfire is a two
DTC’s
after
the MIL has been extinguished.
trip failure. The MIL will
illuminate and blink at
the first failure.
3
GENERAL INFORMATION
OBDII Monitor Run Process
The following procedure has been established to
assist Technicians in the field with enabling and
running OBDII Monitors. The order listed in the
following procedure is intended to allow the techni-
cian to effectively complete each monitor and to set
the CARB Readiness Status in the least time pos-
sible.
**NOTE**
A. Once the monitor run process has begun, do
not turn off the ignition. By turning the igni-
tion key off, monitor enabling conditions will
be lost. NVLD Monitor runs after key off.
B. By performing a Battery Disconnect, or Se-
lecting Erase DTCs, the CARB Readiness and
all additional OBDII information will be
cleared.
Monitor Preliminary Checks:
1. Plug a DRBIII
t into the vehicle’s DLC.
2. Turn the ignition, KEY ON–ENGINE OFF.
Watch for MIL lamp illumination during the
bulb check. MIL lamp must have illuminated, if
not, repair MIL lamp.
3. On the DRB III
t Select #1 DRB III Standalone.
4. Select #1 1998-2005 Diagnostics
5. Select #1 Engine
6. Select #2 DTCs and Related Functions
7. Select #1 Read DTCs
*Verify that No Emissions Related DTCs are
Present.
*If an Emissions DTC is Present, the OBD II
Monitors may not run and the CARB Readiness
will not update.
*The Emissions related DTC, will need to be
repaired, then cleared. By clearing DTCs, the
OBD Monitors will need to be run and completed
to set the CARB Readiness Status.
8. Return to Engine Select Function Menu and
Select #9, OBD II Monitors.
9. Select #3 CARB Readiness Status.
Do all the CARB Readiness Status Locations read
YES?
*YES, then all monitors have been completed and
this vehicle is ready to be I/M or Emission Tested.
*NO, then the following procedure needs to be
followed to run/complete all available monitors.
**NOTE**
A. Only the monitors, which are not YES in the
CARB Readiness Status, need to be completed.
B. Specific criteria need to be met for each monitor.
Each monitor has a Pre-Test screen to assist in
running the monitor.
For additional information, refer to the Chrysler
Corporation Technical Training Workbook titled
On Board Diagnostics: OBDII/EOBD, part num-
ber 81-699-01050.
The most efficient order to run the monitors has
been outlined below, including suggestions to aid
the process.
A. NATURAL VACUUM LEAK DETECTION WITH
PURGE MONITOR
This monitor requires a cool down cycle, usually
an overnight soak for at least 8 hours without the
engine running. The ambient temperature must
decrease overnight – parking the vehicle outside is
advised. To run this test the fuel level must be
between 15-85% full. For the monitor run condi-
tions select the EVAP MON PRE-TEST in the
DRB III
t, OBD II Monitors Menu. The Purge mon-
itor will run if the small leak test reports a pass.
Criteria for NVLD monitor.
1. Engine off time greater than @ one hour
2. Fuel Level between 15% and 85%
3. Start Up ECT and IAT within 10°C (18°F).
4. Vehicle started and run until Purge Monitor
reports a result.
NOTE: If the vehicle does not report a result
and the conditions were correct. It may take
up to two weeks to fail the small leak monitor.
DO NOT use this test to attempt to determine
a
fault.
Use
the
appropriate
service
information procedure for finding a small
leak. If there are no faults and the conditions
are correct this test will run and report a
pass. Note the Small leak test can find leaks
less than 10 thousandths of an inch. If a
small leak is present it takes approximately
one week of normal driving to report a failure.
B. CATALYST/O2 MONITOR
With NGC, Catalyst and O2 Monitor information
are acquired and processed at the same time. Most
vehicles will need to be driven at highway speed
(<50 mph) for a few minutes. Some trucks run the
monitor at idle in drive. If the vehicle is equipped
with a manual transmission, using 4
th
gear may
assist in meeting the monitor running criteria. For
the monitor run conditions, select the BANK 1 CAT
MON PRE-TEST in the DRB III
t, OBD II Monitors
Menu.
C. EGR MONITOR
The EGR monitor now runs in a closed throttle
decel or at idle on a warm vehicle. However, it is
necessary to maintain the TPS, Map and RPM
ranges to allow the monitor to complete itself. For
4
GENERAL INFORMATION
the monitor run conditions, select the EGR PRE-
TEST in the DRB III
t, OBD II Monitors Menu.
D. 02 SENSOR HEATER MONITOR
This monitor is now continuously running once
the heaters are energized. Pass information will be
processed at power down. For the monitor run
conditions, select the O2S HEATER MON PRE-
TEST in the DRB III
t, OBD II Monitors Menu.
3.2.3
OTHER CONTROLS
CHARGING SYSTEM
The charging system is turned on when the
engine is started. The Generator field is control by
the PCM using a 12-volt high-side driver and a body
ground circuit. The Generator output voltage is
determined by the PCM. When more system voltage
is needed, the PCM will applies a longer duty cycle
using the 12-volt high-side drive and shortens duty
cycle or none at all when less voltage is needed.
O2 SENSOR
The O2 system with ignition on and engine off
has a normalized O2 voltage of around 5 volts as
displayed on the DRBIII or measured with a high
impedance voltmeter. As the O2 sensor starts gen-
erating a signal the voltage will move towards 2.5
volts. The voltage will typically vary between 2.5
volts and 3.5 volts on a normal running engine. The
goal voltage is also typically between 2.5 and 3.5
volts. This implies that the 0-volt through 1-volt
range that you are used to is still valid, only it is
shifted up by a 2.5 volt offset. This 2.5 volt supply is
being delivered through the sensor return line.
SPEED CONTROL SYSTEM
The PCM controls vehicle speed by operation of
the speed control servo vacuum and vent solenoids.
Energizing the vacuum solenoid applies vacuum to
the servo to increase throttle position. Operation of
the vent solenoid slowly releases the vacuum allow-
ing throttle position to decrease. A special vacuum
dump solenoid allows immediate release of the
throttle during speed control operation.
Speed control may be cancelled by braking, driver
input using the speed control switches, shifting into
neutral, excessive engine speed (wheels spinning),
or turning the ignition off.
NOTE: If two speed control switches are
selected simultaneously, the PCM will detect
an illegal switch operation and turn the speed
control off.
NATURAL VACUUM LEAK DETECTION (NVLD)
The Natural Vacuum Leak Detection (NVLD)
system is the next generation evaporative leak
detection system that will first be used on vehicles
equipped with the Powertrain Control Module
(PCM) or Next Generation Controller (NGC) start-
ing in 2002 M.Y. This new system replaces the leak
detection pump as the method of evaporative sys-
tem leak detection. The current CARB requirement
is to detect a leak equivalent to a 0.020
9 (0.5 mm)
hole. This system has the capability to detect holes
of this size very dependably.
The basic leak detection theory employed with
NVLD is the
9Gas Law9. This is to say that the
pressure in a sealed vessel will change if the tem-
perature of the gas in the vessel changes. The vessel
will only see this effect if it is indeed sealed. Even
small leaks will allow the pressure in the vessel to
come to equilibrium with the ambient pressure.
In addition to the detection of very small leaks,
this system has the capability of detecting medium
as well as large evaporative system leaks.
THE NVLD UTILIZES THE GAS LAW
PRINCIPLES
A vent valve seals the canister vent during engine
off conditions. If the vapor system has a leak of less
than the failure threshold, the evaporative system
will be pulled into a vacuum, either due to the cool
down from operating temperature or diurnal ambi-
ent temperature cycling. The diurnal effect is con-
sidered one of the primary contributors to the leak
determination by this diagnostic. When the vacuum
in the system exceeds about 1
9 H2O (0.25 KPA), a
vacuum switch closes. The switch closure sends a
signal to the PCM. The PCM, via appropriate logic
strategies (described below), utilizes the switch
signal, or lack thereof, to make a determination of
whether a leak is present.
THE NVLD DEVICE AND HOW IT FUNCTIONS
The NVLD Assembly is designed with a normally
open vacuum switch, a normally closed solenoid,
and a seal, which is actuated by both the solenoid
and a diaphragm. The NVLD is located on the
atmospheric vent side of the canister.
The normally open vacuum switch will close with
about 1
9 H2O (0.25 KPA) vacuum in the evaporative
system. The diaphragm actuates the switch. This is
above the opening point of the fuel inlet check valve
in the fill tube so cap off leaks can be detected.
Submerged fill systems must have recirculation
lines that do not have the in-line normally closed
check valve that protects the system from failed
nozzle liquid ingestion, in order to detect cap off
conditions.
5
GENERAL INFORMATION
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