Kia Carens: Engine Control System / Description and operation
1. Overview
The California Air Resources Board (CARB) began regulation of On Board Diagnostics
(OBD) for vehicles sold in California beginning with the 1988 model year. The
first phase, OBD-I, required monitoring of the fuel metering system, Exhaust
Gas Recirculation (EGR) system and additional emission related components. The
Malfunction Indicator Lamp (MIL) was required to light and alert the driver
of the fault and the need for repair of the emission control system. Associated
with the MIL was a fault code or Diagnostic Trouble Code (DTC) idenfying the
specific area of the fault.
The OBD system was proposed by CARB to improve air quality by identifying vehicle
exceeding emission standards. Passage of the Federal Clean Air Act Amendments
in 1990 has also prompted the Environmental Protection Agency (EPA) to develop
On Board Diagnostic requirements. CARB OBD-II regulations were followed until
1999 when the federal regulations were used.
The OBD-II system meets government regulations by monitoring the emission control
system. When a system or component exceeds emission threshold or a component
operates outside tolerance, a DTC will be stored and the MIL illuminated.
The diagnostic executive is a computer program in the Engine Control Module
(ECM) or PowertrainControl Module (PCM) that coordinates the OBD-II self-monitoring
system. This program controls all the monitors and interactions, DTC and MIL
operation, freeze frame data and scan tool interface.
Freeze frame data describes stored engine conditions, such as state of the engine,
state of fuel control, spark, RPM, load and warm status at the point the first
fault is detected. Previously stored conditions will be replaced only if a fuel
or misfire fault is detected. This data is accessible with the scan tool to
assist in repairing the vehicle.
The center of the OBD-II system is a microprocessor called the Engine Control
Module (ECM) or Powertrain Control Module(PCM).
The ECM or PCM receives input from sensors and other electronic components (switches,
relays, and others) based on information received and programmed into its memory
(keep alive random access memory, and others), the ECM or PCM generates output
signals to control various relays, solenoids and actuators.
2. Configuration of hardware and related terms
1) GST (Generic scan tool)
2) MIL (Malfunction indication lamp) - MIL activity by transistor
The Malfunction Indicator Lamp (MIL) is connected between ECM or PCM-terminal
Malfunction Indicator Lamp and battery supply (open collector amplifier).
In most cars, the MIL will be installed in the instrument panel. The lamp amplifier
can not be damaged by a short circuit.
Lamps with a power dissipation much greater than total dissipation of the MIL
and lamp in the tester may cause a fault indication.
▷ At ignition ON and engine revolution (RPM)< MIN. RPM, the MIL is switched
ON for an optical check by the driver.
3) MIL illumination
When the ECM or PCM detects a malfunction related emission during the first
driving cycle, the DTC and engine data are stored in the freeze frame memory.
The MIL is illuminated only when the ECM or PCM detects the same malfunction
related to the DTC in two consecutive driving cycles.
4) MIL elimination
● Misfire and Fuel System Malfunctions:
For misfire or fuel system malfunctions, the MIL may be eliminated if the same
fault does not reoccur during monitoring in three subsequent sequential driving
cycles in which conditions are similar to those under which the malfunction
was first detected.
● All Other Malfunctions:
For all other faults, the MIL may be extinguished after three subsequent sequential
driving cycles during which the monitoring system responsible for illuminating
the MIL functions without detecting the malfunction and if no other malfunction
has been identified that would independently illuminate the MIL according to
the requirements outlined above.
5) Erasing a fault code
The diagnostic system may erase a fault code if the same fault is not re-registered
in at least 40 engine warm-up cycles, and the MIL is not illuminated for that
fault code.
6) Communication Line (CAN)
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Bus Topology : Line (bus) structure
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Wiring : Twisted pair wire
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Off Board DLC Cable Length : Max. 5m
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Service Mode (Upgrade, Writing VIN) : 500 or 1Mbps)
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7) Driving cycle
A driving cycle consists of engine start up, and engine shut off.
8) Warm-up cycle
A warm-up cycle means sufficient vehicle operation such that the engine coolant
temperature has risen by at least 40 degrees Fahrenheit from engine starting
and reaches a minimum temperature of at least 160 degrees Fahrenheit.
9) Trip cycle
A trip means vehicle operation (following an engine-off period) of duration
and driving mode such that all components and systems are monitored at least
once by the diagnostic system except catalyst efficiency or evaporative system
monitoring when a steady-speed check is used, subject to the limitation that
the manufacturer-defined trip monitoring conditions shall all be encountered
at least once during the first engine start portion of the applicable FTP cycle.
10) DTC format
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Diagnostic Trouble Code (SAE J2012)
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DTCs used in OBD-II vehicles will begin with a letter and are followed
by four numbers.
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The letter of the beginning of the DTC identifies the function of the monitored
device that has failed. A "P" indicates a powertrain device, "C" indicates a
chassis device. "B" is for body device and "U" indicates a network or data link
code. The first number indicates if the code is generic (common to all manufacturers)
or if it is manufacturer specific. A "0" & "2" indicates generic, "1" indicates
manufacturer-specific. The second number indicates the system that is affected
with a number between 1 and 7.
The following is a list showing what numbers are assigned to each system.
2) |
Fuel and air metering(injector circuit malfunction only)
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3) |
Ignition system or misfire
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4) |
Auxiliary emission controls
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5) |
Vehicle speed controls and idle control system
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6) |
Computer output circuits
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The last two numbers of the DTC indicates the component or section of the system
where the fault is located.
11) Freeze frame data
When a freeze frame event is triggered by an emission related DTC, the ECM or
PCM stores various vehicle information as it existed the moment the fault ocurred.
The DTC number along with the engine data can be useful in aiding a technician
in locating the cause of the fault. Once the data from the 1st driving cycle
DTC ocurrence is stored in the freeze frame memory, it will remain there even
when the fault ocurrs again (2nd driving cycle) and the MIL is illuminated.
d. |
Fuel Pressure (if available)
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e. |
Vehicle Speed (if available)
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g. |
Intake Manifold Pressure (if available)
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h. |
Closed-or Open-loop operation
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3. OBD-II system readiness tests
1) Catalyst monitoring
The catalyst efficiency monitor is a self-test strategy within the ECM or PCM
that uses the downstream Heated Oxygen Sensor (HO2S) to determine when a catalyst
has fallen below the minimum level of effectiveness in its ability to control
exhaust emission.
2) Misfire monitoring
Misfire is defined as the lack of proper combustion in the cylinder due to the
absence of spark, poor fuel metering, or poor compression. Any combustion that
does not occur within the cylinder at the proper time is also a misfire. The
misfire detection monitor detects fuel, ignition or mechanically induced misfires.
The intent is to protect the catalyst from permanent damage and to alert the
customer of an emission failure or an inspection maintenance failure by illuminating
the MIL . When a misfire is detected, special software called freeze frame data
is enabled. The freeze frame data captures the operational state of the vehicle
when a fault is detected from misfire detection monitor strategy.
3) Fuel system monitoring
The fuel system monitor is a self-test strategy within the ECM or PCM that monitors
the adaptive fuel table The fuel control system uses the adaptive fuel table
to compensate for normal variability of the fuel system components caused by
wear or aging. During normal vehicle operation, if the fuel system appears biased
lean or rich, the adaptive value table will shift the fuel delivery calculations
to remove bias.
4) Engine cooling system monitoring
The cooling system monitoring is a self-test strategy within the ECM or PCM
that monitors ECTS (Engine Coolant Temperature Sensor) and thermostat about
circuit continuity, output range, rationality faults.
5) O2 sensor monitoring
OBD-II regulations require monitoring of the upstream Heated O2 Sensor (H2OS)
to detect if the deterioration of the sensor has exceeded thresholds. An additional
HO2S is located downstream of the Warm-Up Three Way Catalytic Converter (WU-TWC)
to determine the efficiency of the catalyst.
Although the downstream H2OS is similar to the type used for fuel control, it
functions differently. The downstream HO2S is monitored to determine if a voltage
is generated. That voltage is compared to a calibrated acceptable range.
6) Evaporative emission system monitoring
The EVAP. monitoring is a self-test strategy within the ECM or PCM that tests
the integrity of the EVAP. system. The complete evaporative system detects a
leak or leaks that cumulatively are greater than or equal to a leak caused by
a 0.040 inch and 0.020 inch diameter orifice.
7) Air conditioning system monitoring
The A/C system monitoring is a self-test strategy within the ECM or PCM that
monitors malfunction of all A/C system components at A/C ON.
8) Comprehensive components monitoring
The comprehensive components monitoring is a self-test strategy within the ECM
or PCM that detects fault of any electronic powertrain components or system
that provides input to the ECM or PCM and is not exclusively an input to any
other OBD-II monitor.
9) A/C system component monitoring
Requirement:
If a vehicle incorporates an engine control strategy that alters off idle fuel
and/or spark control when the A/C system is on, the OBD II system shall monitor
all electronic air conditioning system components for malfunctions that cause
the system to fail to invoke the alternate control while the A/C system is on
or cause the system to invoke the alternate control while the A/C system is
off.
Additionally, the OBD II system shall monitor for malfunction all electronic
air conditioning system components that are used as part of the diagnostic strategy
for any other monitored system or component.
Implementation plan:
No engine control strategy incorporated that alters offidle fuel and/or spark
control when A/C system is on. Malfuction of A/C system components is not used
as a part of the diagnostic strategy for other monitored system or component.
Components Location
1. Engine Control Module (ECM)
2. Manifold Absolute Pressure Sensor (MAPS)
3. Intake Air Temperature Sensor (IATS)
4. Engine Coolant Tem ...
Other information:
When you stop for fuel:
Check the engine oil level.
Check coolant level in coolant reservoir.
Check the windshield washer fluid level.
Look for low or under-inflated tires.
Check the radiator and condenser.
Check if the front of the radiator and condenser are clean and not blocked with
leave ...
Adjustment
Battery Charging
In general, vehicle battery charging system has three forms.
1.
Constant current charge: The battery voltage gradually rises by charging
with setting a constant current. If charging current and time are not
managed c ...