1997 SSANGYONG KORANDO ESP

M162 ENGINE MECHANICAL 1B1 -- 43
D AEW OO M Y_2000
Color Dot
MarkingCrankshaft Journal Diameter
(mm)
Blue57.960 -- 57.965
Yellow57.955 -- 57.960
Red57.950 -- 57.955
White57.945 -- 57.950
Violet57.940 -- 57.945
Selection of Crankshaft Main Bearing
1. Crankcase Side
There are seven punching marks on the mating sur-
face to oil pan. This mark is correspondent to the
bearing distinguished by color. Select the relevant
bearing according to the punching mark when re-
paired.
Punching
Mark
Bearing Color Selected
FBlue
FFYellow
FFFRed
2. Crankshaft Bearing Cap Side
Select the crankshaft main bearing according to the
marking letter on the crankshaft main journal when
repaired.
Marking
Letter
Bearing Color Selected
BBlue
YYellow
RRed
WWhite
VViolet
Service DataUnit: mm
Crankshaft Stan-
dard and Repair
SizeCrankshaft
Bearing Jour-
nal DiameterCrankshaft
Bearing
DiameterCrankshaft
Journal Width
at fit bearingConnecting Rod
Bearing Journal
DiameterConnecting Rod
Bearing Jourmal
Width
Standard size57.940-- 57.9655824.50-- 24.53347.935-- 47.96527.958-- 28.042
1st repair size57.705-- 57.71547.700-- 47.715
2nd repair size57.450-- 57.46547.450-- 47.465
3rd repair size57.205-- 57.215--47.200-- 47.215--
4th repair size56.955-- 56.96546.950-- 46.965

1B1 -- 60 M162 ENGINE MECHANICAL
D AEW OO M Y_2000
Tools Required
DW110 -- 120 Holding Pin
Inspection
1. Position the No.1 cylinder piston to TDC (OT) by turn-
ing the crankshaft.
Notice:When the OT mark on vibration damper is
aligned with timing gear case cover, the intake and ex-
haust cam of cylinderwill make the slope to the center
and will face up. In this way, the adjustment hole of the
intake and exhaust camshaftwill match in line with the
cylinder head upper end, at 3 o’clock, and 9 o’clock di-
rection each other.
2. Check the timing as below procedure;
-- Check if the camshaft adjustment hole is posi-
tioned to 3 o’clock direction at the intake side and
to 9 o’clock direction at the exhaust side, respec-
tively and align with the cylinder head mating sur-
face.
-- At this condition, check if the OT mark on vibration
damper aligns with the marker on the timing gear
case.
Adjustment Procedure
1. Position the No.1 cylinder to BTDC 30°.
2. Remove the chain tensioner.
3. Remove the exhaust camshaft sprocket.
4. Align the intake and exhaust camshaft flange hole
with the cylinder head upper surface.
DIntake Side : 3 o’clock direction
DExhaust Side : 9 o’clock direction
5. Align the holes on intake and exhaust camshaft to the
hole on cylinder head. Insert the holding pin
DW110-- 120 into the holes.
6. Secure the intake and exhaust camshaft.
7. Position the piston of No.1 cylinder at TDC (OT) by
turning the crankshaft.
8. Turn the camshaft adjuster of the intake camshaft to
the left as much as possible (cam adjuster ‘retarded’
position).
9. Install the chain to the intake camshaft sprocket.
Notice:Timing chain must be placed on the guide rail in
gear case cover.

M162 ENGINE CONTROLS 1F1 -- 15
D AEW OO M Y_2000
FAILURE CODES TABLE (Cont’d)
Failure
codeSee
PageDescription
401F1 -- 51Purge control valve short circuit to battery
411F1 -- 51Purge control valve short circuit to ground or open
441F1 -- 72Cooling fan (HI) relay short circuit to power
451F1 -- 72Cooling fan (HI) relay short circuit to ground or open
541F1 -- 51Purge control circuit malfunction
561F1 -- 33No.1 knock sensor signal failure
571F1 -- 33No.2 knock sensor signal failure
581F1 -- 27Camshaft position sensor signal : No.1 cylinder synchronization failure
591F1 -- 89CAN communication failure : MSR data transmission not plausible
601F1 -- 89CAN communication failure : ASR data transmission not plausible
621F1 -- 71Clutch switch defective
641F1 -- 21No ignition voltage output (No.1 ignition coil)
651F1 -- 21No ignition voltage output (No.2 ignition coil)
661F1 -- 21No ignition voltage output (No.3 ignition coil)
671F1 -- 23Crankshaft position sensor adaptation failure
681F1 -- 35Random/Multiple Misfire
711F1 -- 39Starter signal recognition failure
721F1 -- 47No.1 injector short circuit to battery
731F1 -- 47No.1 injector short circuit to ground or open
741F1 -- 47No.2 injector short circuit to battery
751F1 -- 47No.2 injector short circuit to ground or open
761F1 -- 47No.3 injector short circuit to battery
771F1 -- 48No.3 injector short circuit to ground or open
781F1 -- 48No.4 injector short circuit to battery
791F1 -- 48No.4 injector short circuit to ground or open
801F1 -- 82Oxygen sensor high voltage
811F1 -- 83Bank 1 system short term fuel trim adaptation below lean threshold
821F1 -- 82Oxygen sensor no activity detected
831F1 -- 82Oxygen sensor not lean after overrun fuel shut -- off
841F1 -- 82Oxygen sensor slow response
851F1 -- 82Oxygen sensor heater failure
861F1 -- 82Oxygen sensor heater short circuit to battery
871F1 -- 82Oxygen sensor heater short circuit to ground or open
891F1 -- 82Oxygen sensor low voltage
931F1 -- 83Bank 1 system short term fuel trim adaptation above rich threshold
961F1 -- 83Bank 1 system short term fuel trim at rich stop
971F1 -- 83Bank 1 system short term fuel trim at lean stop
981F1 -- 83Bank 1 system idle adaptation failure (above rich threshold)
991F1 -- 83Bank 1 system idle adaptation failure (below lean threshold)
1001F1 -- 83Bank 1 system learning control failure (rich, low load)
1011F1 -- 83Bank 1 system learning control failure (lean, low load)
1021F1 -- 83Bank 1 system learning control failure (rich, high load)

M162 ENGINE CONTROLS 1F1 -- 21
D AEW OO M Y_2000
KAB1F140
Failure
CodeDescriptionTrouble AreaMaintenance Hint
64
No ignition voltage
output (No. 1 ignition
coil)DInspectiontheECMpin70(71and72)
about short circuit or open with bad
contact
DInspectionthepowersourcetoignition
65
No ignition voltage
output (No. 2 ignition
coil)Malfunction of ignition circuit
Primary current values or
secondary short circuit
DInspectionthepowersourcetoignition
coil
DInspection the ignition coil, high
tension cords etc.
DInspectionthesparkplug(wetcracks
66
No ignition voltage
output (No. 3 ignition
coil)DInspection the spark plug (wet, cracks,
wear, improper gap, burned
electrodes, heavy deposit)
DInspection the ECM
Circuit Description
The Electronic Ignition (EI) system uses a waste spark method of spark distribution. The Crankshaft Position (CKP)
sensor sends reference pulses to the ECM. The ECM then triggers the EI system ignition coils. Once the ECM triggers
the EI system ignition coils both of the connected spark plugs fire at the same time. One cylinder is on its compression
stroke at the same time that the other is on the exhaust stroke, resulting in lower energy needed to fire the spark plug in
the cylinder on its exhaust stroke.
This leaves the remainder of the high voltage to be used to fire the spark plug in the cylinder on its compression stroke.
Since the CKP sensor is in a fixed position, timing adjustments are not possible or needed.

1F1 -- 30 M162 ENGINE CONTROLS
D AEW OO M Y_2000
CAMSHAFT ACTUATOR
YAA1F300
When the engine is running, the camshaft actuator rotates the intake camshaft hydraulically and mechanically relative
to the camshaft sprocket by 32°crank angle to the “advanced” position and back to the “retard” position.
The camshaft actuator is actuated electro-mechanically by the Engine Control Module (ECM). The positioning time of
apporx. 1 second is dependent on the engine oil pressure at the camshaft actuator and on the oil viscosity and oil
temperature, respectively.
The camshaft indicator on the camshaft sprocket provides the camshaft rotational speed to the position sensor as an
input parameter for the engine ignition control unit.
Operation Condition of Camshaft Actuator
Engine RPMCamshaft PositionEffect
Engine stopRetard--
0 ~ 1,500 rpmRetard
Idle speed is improved
Blow-by gas is decreased
Valve overlap is decreased
1,500 ~ 4,300 rpmAdvanced
Torque is increased
Fuel loss is decreased
NOx is decreased
Above 4,300 rpmRetardEngine overrun is prohibited

1F1 -- 40 M162 ENGINE CONTROLS
D AEW OO M Y_2000
FUEL SYSTEM
The function of the fuel metering system is to deliver the correct amount of fuel to the engine under all operating condi-
tions. The fuel is delivered to the engine by the individual fuel injectors mounted into the intake manifold near each
cylinder.
The main fuel control sensors are the Mass Air Flow (MAF) sensor and the oxygen (O2) sensors.
The MAF sensor monitors the mass flow of the air being drawn into the engine. An electrically heated element is
mounted in the intake air stream, where it is cooled by the flow of incoming air. Engine Control Module (ECM) modu-
lates the flow of heating current to maintain the temperature differential between the heated film and the intake air at a
constant level. The amount of heating current required to maintain the temperature thus provides an index for the
mass air flow. This concept automatically compensates for variations in air density, as this is one of the factors that
determines the amount of warmth that the surrounding air absorbs from the heated element. MAF sensor is located
between the air filter and the throttle valve.
Under high fuel demands, the MAF sensor reads a high mass flow condition, such as wide open throttle. The ECM
uses this information to enrich the mixture, thus increasing the fuel injector on-- time, to provide the correct amount of
fuel. When decelerating, the mass flow decreases. This mass flow change is sensed by the MAF sensor and read by
the ECM, which then decreases the fuel injector on-- time due to the low fuel demand conditions.
The O2 sensors are located in the exhaust pipe before catalytic converter. The O2 sensors indicate to the ECM the
amount of oxygen in the exhaust gas, and the ECM changes the air/fuel ratio to the engine by controlling the fuel
injectors. The best air/fuel ratio to minimize exhaust emissions is 14.7 to 1, which allows the catalytic converter to
operate most efficiently. Because of the constant measuring and adjusting of the air/fuel ratio, the fuel injection system
is called a “closed loop” system.
The ECM uses voltage inputs from several sensors to determine how much fuel to provide to the engine. The fuel is
delivered under one of several conditions, called ‘‘modes”.
Starting Mode
When the ignition is turned ON, the ECM turns the fuel pump relay on for 1 second. The fuel pump then builds fuel
pressure. The ECM also checks the Engine Coolant Temperature (ECT) sensor and the Throttle Position (TP) sensor
and determines the proper air/fuel ratio for starting the engine. This ranges from 1.5 to 1 at -- 36°C(--33°F) coolant
temperature to 14.7 to 1 at 94°C (201°F) coolant temperature. The ECM controls the amount of fuel delivered in the
starting mode by changing how long the fuel injector is turned on and off. This is done by ‘‘pulsing” the fuel injectors for
very short times.
Run Mode
The run mode has two conditions called ‘‘open loop” and ‘‘closed loop”.
Open Loop
When the engine is first started and it is above 690 rpm, thesystem goes into “open loop” operation. In “open loop”, the
ECM ignores the signal from the HO2S and calculates the air/fuel ratio based on inputs from the ECT sensor and the
MAF sensor. The ECM stays in “open loop” until the following conditions are met:
DThe O2 has a varying voltage output, showing that it is hot enough to operate properly.
DThe ECT sensor is above a specified temperature (22.5°C).
DA specific amount of time has elapsed after starting the engine.
Closed Loop
The specific values for the above conditions vary with different engines and are stored in the Electronically Erasable
Programmable Read -- Only Memory (EEPROM). When these conditions are met, thesystem goes into “closed loop”
operation. In “closed loop”, the ECM calculates the air/fuel ratio (fuel injector on-- time) based on the signals from the
O2 sensors. This allows the air/fuel ratio to stay very close to 14.7 to 1.
Acceleration Mode
The ECM responds to rapid changes in throttle position and airflow and provides extra fuel.
Deceleration Mode
The ECM responds to changes in throttle position and airflow and reduces the amount of fuel. When deceleration is
very fast, the ECM can cut off fuel completely for short periods of time.

1F1 -- 68 M162 ENGINE CONTROLS
D AEW OO M Y_2000
ACCELERATOR PEDAL MODULE
YAA1F620
The Acceleration Pedal Position (APP) sensor is mounted on the accelerator pedal assembly. The sensor is actually
two individual APP sensors and one housing. This sensor works with the Throttle Position (TP) sensor to provide input
to the Engine Control Module (ECM) regarding driver requested accelerator pedal and throttle angle at the throttle
body.
When the APP sensor is defected:
When the APP 1 or APP 2 sensor is defected condition, the engine is still running at idle condition but, the accelerator
pedal reaction is not response correctly and also, the engine rpmwill be reacted to 4,000 rpm slowly. If the APP 1
sensor is out of order, the APP 2 sensor will be conducted with signal as a default signal but, the throttle valve opening
is limited 60% and delayed opening speed.
When the TP sensor or servo motor is defected:
When the TP 1, 2 sensor or servo motor is defected condition, the throttle valvewill be closed to the spring capsule by
spring force, at this condition, the throttle valvewillopen 10°~20°and engine rpmwill be controlled by ECM will
opening (On/Off) time of injector. Theengine rpmwill be maintaining 900 rpm (at idle) to 1,800 according to theengine
load.

M162 ENGINE CONTROLS 1F1 -- 69
D AEW OO M Y_2000
KAB1F270
Failure
CodeDescriptionTrouble AreaMaintenance Hint
122
Acceleration pedal
position sensor signal
failureWhen malfunction of APP
Sensor
160
Acceleration pedal
position 1 sensor low
voltageAPP 1 sensor short circuit to
ground or open
161
Acceleration pedal
position sensor 1 high
voltageAPP 1 sensor short circuit to
power
DMonitoring the actual values through
162
Acceleration pedal
position sensor 2 low
voltageAPP 2 sensor short circuit to
ground or open
Monitoringtheactualvaluesthrough
scan tool
DInspection the ECM pin 31, 47, 32, 48,
59, 51 about short circuit or open with
badcontact
163
Acceleration pedal
position sensor 2 high
voltageAPP 2 sensor short circuit to
power
badcontact
DInspection the APP sensor
DInspection the ECM
164
Accelerator pedal
position sensor 1 not
plausible with
accelerator pedal
position sensor 2
When difference between
APP 1 sensor and APP 2
sensor
167
Both setpoint
Accelerator pedal
position sensor defectiveWhen defective of both APP
sensor
Circuit Description
The ECM supplies a 5 or 2.5 volt reference signal and a ground to the APP sensor 1 or 2. The ECM calculates on these
signal lines. The APP sensor output changes as the accelerator pedal is moved. The output of the APP 1 and APP 2
sensor are low, about 0.4 ~ 0.7 volts and 0.2 ~ 0.35 volts respectively at the closed throttle position. As pushing the
accelerator pedal, the output increases so that the output voltageswill be about 4.3 ~ 4.8 volts and 2.1 ~ 2.4 volts
individually when accelerating fully with the kick down, at Wide Open Throttle (WOT).