Transcript
EG-147
ENGINE – 1KD-FTV AND 2KD-FTV ENGINES ENGINE
CONTROL SYSTEM
1. General The engine control system of the 1KD-FTV and 2KD-FTV engines has the following system.
2KD-FTV 2KD-FTV High Version
System
Outline
1KD-FTV
Fuel Injection Volume Control (See page EG-156)
Based on the signals received from the sensors, the engine ECU determines the fuel injection volume in accordance with the engine condition.
Fuel Injection Timing Control (See page EG-157)
Based on the signals received from the sensors, the engine ECU determines the fuel injection timing in accordance with the engine condition.
During Starting Control (See page EG-158)
To facilitate startability, the engine ECU optimally controls the injection volume and injection timing during starting.
Idle Speed Control (See page EG-159)
The engine ECU determines the idle speed in accordance with the engine condition, and controls the fuel injection volume in order to maintain the target idle speed.
Fuel Pressure Control (See page EG-160) Pilot Injection Control (See page EG-163)
Based on the signals received from the sensors, the engine ECU determines the fuel pressure via SCV (Suction Control Valve) in accordance with the engine condition. Based on the signals received from the sensors, the engine ECU determines pilot injection volume/timing, and interval (between pilot injection and main injection) in accordance with the engine condition.
Glow Plug Control
Controls the length of time when the current is applied to the glow plugs, in accordance with the coolant temperature.
Controls the intake shutter valve (throttle valve) opening angle in accordance with the engine condition. Fully close the intake shutter valve (throttle valve) in order to reduce the vibration when the engine is stopped.
Swirl Control (See page EG-164)
Based on the signals received from the sensors, the engine ECU controls the vacuum that is directed to the actuator via the VSV, in order to open and close the valve.
Turbocharger Control (See page EG-165)
Based on the signals received from the sensors, the engine ECU controls the actuator in accordance with the engine condition.
EGR Control (See page EG-169)
Controls the EGR volume via EGR valve in accordance with the engine condition.
Air Conditioner Cut-Off Control*1
By controlling the air conditioner compressor ON or OFF in accordance with the engine condition, drivability is maintained.
Engine Immobilizer*2
Prohibits fuel injection if an attempt is made to start the engine with an invalid ignition key.
Diagnosis (See page EG-171)
When the engine ECU detects a malfunction, the engine ECU diagnoses and memorizes the failed section.
Fail-Safe (See page EG-171)
When the engine ECU detects a malfunction, the engine ECU stops or controls the engine according to the data already stored in the memory.
Intake Shutter Control (See page EG-164)
*1: Models with Air Conditioner *2: Models with Engine Immobilizer System
EG-148
ENGINE – 1KD-FTV AND 2KD-FTV ENGINES
2. Construction The configuration of the engine control system in the 1KD-FTV and 2KD-FTV engines is as shown in the following chart. INTAKE SHUTTER VALVE POSITION SENSOR
#1
VLU
#2 #3
CAMSHAFT POSITION SENSOR
G
#4
No.1 INJECTOR
E D U
No.2 INJECTOR No.3 INJECTOR No.4 INJECTOR
INJF CRANKSHAFT CRANKSHAFT POSITION SENSOR
FUEL PRESSURE SENSOR
TURBO PRESSURE SENSOR
INTAKE AIR TEMP. SENSOR
WATER TEMP. SENSOR
ACCELERATOR ACCELERATOR PEDAL POSITION SENSOR
NE PCV PCR1 INTAKE SHUTTER CONTROL
LUSL
PIM
EGR THW
Engine ECU
EGRC
VSV (for EGR Valve Close)* 1
GLOW PLUG CONTROL
VPA2
Glow Plug Relay
VG
THF SCV
INTAKE AIR TEMP. TEMP. SENSOR SEN SOR *
Vacuum Regulating Valve (for EGR Valve Control)
VPA
IREL
FUEL TEMP. SENSOR
Torque Motor (Rotary Solenoid type)
EGR CONTROL
THA
GREL
AIR FLOW METER*
SUCTION CONTROL VALVE
EDU RELAY
VSV (for Swirl Control Control Valve)* Valve)*
THIA TURBOCHARGER CONTROL*
EGR VALVE POSITION SENSOR*3
EGLS
1
VNTO
Turbo Motor Driver VNTI
STOP LIGHT SWITCH
ALTERNATOR
STP ST1ALT
Nozzle Vane Vane Position Sensor
DC Motor
271EG132
(Continued)
EG-149
ENGINE – 1KD-FTV AND 2KD-FTV ENGINES
IGNITION SWITCH
STA
Starting
Signal (ST Terminal) Ignition Signal (IG Terminal)
A/C AMPLIFIER* ACT
IGSW
Magnetic Clutch Actuation Signal
AC1
Engine Idle-Up Signal CRUISE CONTROL MAIN SWITCH *
CCS
BATT
BATTERY
MREL Engine ECU
MAIN RELAY
+B IMO IMI
TRANSPONDER KEY ECU*
TC SIL
DLC3
WFSE
COMBINATION COMBINATION METER W GIND PI SPD DM TACH
6
TRANSMISSION CONTROL ECU*
CAN+
ECT CONTROL
CAN-
THWO
*1: Only for 1KD-FTV Engine *2: Only for Models with Intercooler *3: Only for 2KD-FTV Engine *4: Only for Models with Cruise Control System *5: Only for Models with Engine Immobilizer System *6: Only for Models with Automatic Transmission *7: Only for Models with Air Conditioner System *8: Only for Models with Multi Information Display
Check Engine Warning Light Glow Indicator Light Cruise MAIN Indicator Light*4 Vehicle Speed Signal Injection Volume Signal* Tachometer Water Temp. Signal
271EG133
EG-150
ENGINE – 1KD-FTV AND 2KD-FTV ENGINES
3. Engine Control System Diagram Accelerator Pedal Position Sensor
Ignition Switch Signal Glow Relay
Stop Light Switch Signal Air condit conditioner ioner Signal* Signal* Vehicle Speed Signal Suction Control Valve
Engine ECU
Fuel Temp. Sensor
Supply Pump
Atmospheric Pressure Sensor
VSV*2 (EGR Valve Close)
Common-Rail Fuel Pressure Sensor
Intake Air Temp. Sensor*2
Intake Air Temp. Sensor*3 Intercooler*3
E-VRV
EDU Relay EDU Intake Shutter Assy.
EGR Valve Position Sensor*4 Turbo Pressure Sensor
Air Flow Meter* Intake Air Temp. Sensor*4 DC Motor*2 Nozzle Vane Position Sensor*2
Glow Plug VSV* VSV* (Swirl Control Valve)
Injector Turbo Motor Driver*2
Water Temp. Sensor Camshaft Position Sensor Crankshaft Position Sensor
* : Only for Models with with Air Condition Conditioner er *2: Only for 1KD-FTV Engine
* : Only for Models Models with Intercool Intercooler er *4: Only for 2KD-FTV Engine
271EG134
EG-151
ENGINE – 1KD-FTV AND 2KD-FTV ENGINES
4. Layout of Main Components EDU
E-VRV Turbo Pressure Sensor Air Flow Meter* Meter*
Intake Air Temp. Temp. Sensor* Sensor *2 Glow Plug
Injector
Intake Air Temp. Sensor*3 Intake Shutter Valve Position Sensor
Fuel Pressure Sensor
Torque Motor
(Rotary Solenoid type)
VSV*1 (EGR Valve Close)
EGR Valve 2 Position Sensor*
Water Temp. Sensor
Check Engine Warning Light Glow Indicator Light
VSV*1 (Swirl Control Valve)
Engine ECU Transmission Control ECU* 4
Common-Rail Crankshaft Position Sensor Camshaft Position Sensor
Fuel Temp. Sensor
Stop Light Switch
SCV
Supply Pump
DLC3 Accelerator Pedal Position Sensor
LHD Model 1
* : Only for 1KD-FTV Engine *2: Only for 2KD-FTV Engine *3: Only for Models with Intercooler *4: Only for Models with Automatic Transmission
271EG135
Turbo Motor Driver*1
EG-152
ENGINE – 1KD-FTV AND 2KD-FTV ENGINES
5. Main Components of Engine Control System General The main components of the 1KD-FTV and 2KD-FTV engine control system are as follows: Components
Engine ECU
Outline
32-bit CPU
Quantity
Function
1
The engine ECU effects overall control of the engine control system to suit the operating conditions of the engine in accordance with the signals provided by the sensors.
EDU
DC/DC Converter
1
The EDU is used to drive the injector at high speeds. The EDU has realized high-speed driving under high fuel pressure conditions through the use of a DC/DC converter that provides a high voltage, quickcharging system.
Turbo Pressure Sensor
Semiconductor Silicon Chip Type
1
This sensor uses built-in semiconductors to detect the intake manifold pressure.
Atmospheric Pressure Sensor
Semiconductor Silicon Chip Type
1
This sensor, which is built into the engine ECU, uses semiconductors to detect the atmospheric pressure.
Fuel Pressure Sensor
Semiconductor Strain Gauge Type
1
This sensor uses built-in semiconductors to detect the internal pressure of the common-rail.
Crankshaft Position Sensor
Pick-up Coil Type (Rotor Teeth /36-2)
1
This sensor detects the engine speed and performs the cylinder identification.
Camshaft Position Sensor
Pick-up Coil Type (Rotor Teeth /5)
1
This sensor performs the cylinder identification.
Hot-wire Type
1
Thermistor Type Type
1
Intake Air Temperature Temperature Sensor
Thermistor Type Type
1
Intake Air Temperature Temperature Sensor (for Intercooler)
Thermistor Type Type
1
Fuel Temperature Sensor
Thermistor Type Type
1
This sensor detects the fuel temperature in the supply pump by means of an internal thermistor.
Intake Shutter Valve Position Sensor
No-contact Type Type
1
This sensor detects the intake shutter valve (throttle valve) opening angle.
Air Flow Meter (1KD-FTV Engine) Water Temperature Sensor
This sensor uses a built-in hot-wire to directly detect the intake air volume. This sensor detects the engine coolant temperature by means of an internal thermistor. thermistor. This sensor, which is provided at the air cleaner outlet, detects the intake air temperature by means of an internal thermistor. On the 1KD-FTV engine, this sensor is built into the airflow meter. This sensor, which is provided only on the models with an intercooler, detects the intake air temperature past the intercooler.
Accelerator Pedal Position Sensor EGR Valve Position Sensor (2KD-FTV Engine) SCV Suction Control Valve
Injector
No-contact Type Type
1
This sensor detects the amount of pedal effort applied to the accelerator pedal. The basic construction and operation of this sensor are the same as in the 1TR-FE and 2TR-FE engines. For details, see page EG-46.
Contact Type
1
This sensor detects the actual amount of the EGR valve opening.
Linear Solenoid Valve
1
8-hole Type (1KD-FTV Engine) 6-hole Type (2KD-FTV Engine)
4
The SCV position is controlled by the signals from the ECU, and a fuel volume that suits the SCV position is drawn into the pumping portion (plunger ( plunger portion). The injector contains a solenoid valve that opens and closes to increase or decrease the pressure in the control chamber. This causes the nozzle needle to open and close the valve, which results in fuel injection.
EG-153
ENGINE – 1KD-FTV AND 2KD-FTV ENGINES
Engine ECU The 32-bit CPU of the engine ECU is used to increase the speed for processing the signals. Each of the 2KD-FTV engine and the 2KD-FTV High Version engine is equipped with an engine ECU that contains an engine control program that differs from each other. However, both engine models share the same mechanical components. On the models equipped with the A340E and A340F automatic transmissions, the engine ECU maintains communication with a separate, independent ECT ECU through CAN (Controller Area Network). Thus, engine control control is effected effected in coordination coordination with ECT control. control.
Turbo Pressure Sensor The turbo pressure sensor consists of a semiconductor which utilizes the characteristic of a silicon chip that changes its electrical resistance when pressure is applied to it. The sensor converts the intake air pressure into an an electrical signal, signal, and sends sends it to the engine ECU ECU in an amplified amplified form. Sensor Unit (V) 5
Output Voltage
(kPa)
0
100
250
Intake Manifold Pressure
271EG136
Fuel Pressure Sensor The fuel pressure sensor consists of a semiconductor which utilizes the characteristic of a silicon chip that changes its electrical resistance when pressure is applied to it. This sensor is mounted on the common-rail, common-rail, outputs a signal that represents represents the fuel pressure in the common-rail common-rail to the engine ECU, in order to constantly regulate the fuel at an optimal pressure.
Detection Portion (V)
Output Voltage (MPa) Fuel Pressure
271EG137
EG-154
ENGINE – 1KD-FTV AND 2KD-FTV ENGINES
Crankshaft Crankshaft Position Sensor and Camshaft Position Sensor The timing rotor of the crankshaft consists of 34 teeth, with 2 teeth missing. The crankshaft position sensor outputs the crankshaft rotation signals every 10, and the missing teeth are used to determine the top-dead-center. To detect the camshaft camshaft position, a protrusion that is provided on the timing pulley is used to generate 5 pulse for every every 2 revolution of the crankshaft.
Camshaft Position Sensor
Camshaft Position Sensor
34 Pulse/360 CA
5 Pulse/720 CA
224EG41
Sensor Output Waveforms
5 Pulse/720 CA 180 CA
180 CA
34 Pulse/360 CA
180 CA
34 Pulse/360 CA 271EG138
ENGINE – 1KD-FTV AND 2KD-FTV ENGINES
EG-155
Intake Shutter Valve Position Sensor The intake shutter valve position sensor is mounted on the intake shutter assembly, assembly, to detect the opening angle of the intake shutter valve (throttle valve), the intake shutter valve position sensor converts the magnetic flux density that changes when the magnetic yoke (located on the same axis as the intake shutter valve shaft) rotates around the hall IC into electric signals to operate the intake shutter valve control motor.
Hall IC
5
Output Voltage (V)
Magnet
271EG82
Intake Shutter Valve (Throttle Valve)
0
100 Intake Shutter Valve Position Ratio (%) 271EG83
EG-156
ENGINE – 1KD-FTV AND 2KD-FTV ENGINES
6. Fuel Injection Volume Volume Control The engine ECU calculates two types of values: the basic injection volume and the maximum injection volume. Then, the engine ECU compares the basic and maximum injection volumes, and determines the smaller calculated value to be the final i njection volume. Basic Injection Volume
Accelerator Pedal Position Sensor
Crankshaft Position Sensor Engine Speed
Engine ECU
Calculation of Basic Injection Volume
ISC* Correction Water Temp. Sensor Sens or
*: Idle Speed Control
224EG44
Maximum Injection Volume
Engine ECU Basic/Maximum Injection Volume (Map data inside of ECU)
Crankshaft Position Sensor Engine Speed Water Temp. Temp. Sensor Sens or
Maximum Injection Volume Correction Co rrection
Fuel Temp. Sensor Intake
Air Temp Temp Sensor Turbo Pressure Sensor Air Flow Meter* Intake Air Volume*
224EG46
*: Only for 1KD-FTV Engine Engine
EG-157
ENGINE – 1KD-FTV AND 2KD-FTV ENGINES Final Injection Volume Decision
Engine ECU Basic Injection Volume
Fuel Pressure
Comparison
Final
EDU
Maximum Injection Volume
Injector
224EG48
7. Fuel Injection Timing Control Fuel injection timing is controlled as shown below. below.
Accelerator Pedal Position Sensor
Crankshaft Position Sensor Engine Speed
Engine ECU
Basic Injection Timing
Water Temp. Sensor Sen sor Intake Air Temp. Sensor
Correction
Turbo Pressure Sensor
Injection Timing
EDU
Injection
201EG45
EG-158
ENGINE – 1KD-FTV AND 2KD-FTV ENGINES
8. During Starting Control Injection Volume Control The starting injection volume is determined by adjusting the basic injection volume in accordance with the starter ON signals (ON time) and coolant temperature sensor signals and engine speed signal. When the engine is cold, t he coolant temperature will be lower and the injection volume will be greater. greater.
Engine ECU
Basic Injection Volume +
Starter Signal
Correction
Water Temp. Sensor Crankshaft Position Sensor 224EG50
Injection Timing Control To determine the starting injection timing, the target injection timing is corrected in accordance with the starter signals, water temperature, and engine speed. When the water temperature is low, low, if the engine speed is high, the injection ti ming is advanced.
Engine ECU Starter Signal Target Injection Timing Correction
Water Temp. Sensor Crankshaft Position Sensor
224EG51
EG-159
ENGINE – 1KD-FTV AND 2KD-FTV ENGINES
9. Idle Speed Control Fuel injection timing is controlled as shown below. below.
Engine ECU
Accelerator Pedal Position Sensor Water Temp. Sensor
Target Target Speed S peed Calculation
Vehicle Speed Sensor
Starter Signal A/C Signal* Idle-up Signal Comparison
Actual Engine Speed
Injection Injecti on Volume Volume Correction
Crankshaft Position Sensor
*: with Air Conditioner 233EG14
EG-160
ENGINE – 1KD-FTV AND 2KD-FTV ENGINES
10. Fuel Pressure Control General Engine ECU calculates the target injection pressure (32~160MPa/1KD-FTV, 30~160MPa/2KD-FTV) base on the engine conditions, that are the signals from the acceleration acceleration pedal position sensor and the crankshaft position sensor. To control fuel pressure, signals sent to SCV (Suction Control valve) of the supply pump regulate the pumping volume, so that the pressure detected by the pressure sensor matches matches the target injection pressure. Fuel Pressure Sensor
Pressure Limiter Common-rail
Injector
Supply Pump SCV Fuel Temp. Sensor EDU
Calculation of target injection pressure Engine ECU
Crankshaft Position Sensor
Accelerator Pedal Position Sensor 271EG139
EG-161
ENGINE – 1KD-FTV AND 2KD-FTV ENGINES
System Operation 1) General
The engine ECU controls the opening of the SCV in order to regulate the volume of fuel that is pumped by the supply pump pump to the common-rail. common-rail. Consequently, Consequently, the fuel pressure in the common-rail common-rail is controlled to the target injection pressure.
2) SCV Opening Small
(a) When the opening of the SCV is small, the fuel suction area is kept small, which decrease the transferable fuel quantity. (b) The plunger strokes fully, however, the suction volume becomes small due to the small suction area. Therefore, the difference difference of the volume between the geometry volume and the suction volume i s in vacuum condition. (c) Pumping will start at the time when the fuel pressure has become higher than the common-rail pressure.
Fuel Pumping Mass Plunger TDC
Plunger BDC
Pumping Starting Point
Cam Stroke
SCV
Small Suction Area
(a)
(b)
(c) 245EG13
EG-162
ENGINE – 1KD-FTV AND 2KD-FTV ENGINES
3) SCV Opening Large
(a) When the opening of the SCV is large, the fuel suction area is kept large, which increase the transferable fuel quantity. (b) If the plunger strokes fully, fully, the suction volume will increase because because the suction area is large. (c) Pumping will start at the time when the fuel pressure has become higher than the common-rail pressure. Fuel Pumping Mass
Pumping Starting Point
Cam Stroke
Large Suction Area
(a)
(b)
(c) 245EG14
EG-163
ENGINE – 1KD-FTV AND 2KD-FTV ENGINES
11. Pilot Injection Control Pilot injection is a method that provides an auxiliary fuel injection before the main fuel injection takes place. The purpose purpose of pilot injection is to gently start the combustion combustion of the fuel of the main main injection in order to reduce combustion noise.
State
Pilot Injection Pilot Injection
Ordinarily Injection
Main Injection
Fuel Injection
Combustion Pressure
168EG23
During pilot injection, the pilot injection volume, timing, and interval (Between pilot injection and main injection) are controlled as shown below.
Accelerator Pedal Position Sensor
Crankshaft Position Sensor Engine Speed
Engine ECU Basic Pilot Injection (Volume, Timing, Interval) Intake Air Temp. Sensor Correction
Water Temp. Sensor Turbo Pressure Sensor
Pilot Injection (Volume, Timing, Interval)
EDU
Injection
201EG45
EG-164
ENGINE – 1KD-FTV AND 2KD-FTV ENGINES
12. Intake Shutter Control The opening of the intake shutter valve (throttle valve) that is installed on the intake manifold is controlled by the engine ECU in accordance accordance with engine condition. As a result, the noise that is generated during idling and deceleration, as well as the noise and vibration that are generated when the engine is stopped, have been reduced and this control makes it possible to re-circulate the exhaust gas in accordance with the driving condition.
Intake Shutter Valve Position Sensor
Intake Shutter Valve Control Motor Engine Speed Vehicle Speed Water Temp.
Intake Shutter Valve
Engine ECU
Intake Air Temp. Accelerator Pedal Position Intake Air Pressure
Ignition Switch 271EG140
13. Swirl Control (Only for 1KD-FTV Engine) The engine ECU determines the swirl control valve position (open or closed) based on the engine conditions (engine speed and accelerator pedal effort). Then, it switches the vacuum that is applied to the actuator diaphragm via the VSV, in order to open and close the swirl control valve. In the low engine speed range, the engine ECU closes the swirl control valve to strengthen the swirl in the combustion chamber, thus promoting the mixture of fuel and air and stabilizing combustion. When the engine speed increases to the medium or high-speed range, the engine ECU fully opens the swirl control valve. On a cold engine, the engine ECU fully closes the swirl control valve to reduce the amount of white smoke emissions.
Intake Port
Vacuum Swirl Control Pump Valve Accelerator Pedal Position
Combustion Chamber
Engine Speed Actuator Engine ECU
VSV
271EG90
EG-165
ENGINE – 1KD-FTV AND 2KD-FTV ENGINES
14. Turbo Charger Control Control (Only for 1KD-FTV Engine) General The engine ECU controls the nozzle vane position using the turbo motor driver, in order to obtain the calculated target target turbo pressure appropriate to the engine operating op erating condition. The engine ECU calculates the optimal nozzle vane position in accordance accordance with the driving conditions (engine speed, injection volume, atmospheric pressure, and water temperature etc), and sends a target nozzle vane position signal to the turbo motor driver. driver. The turbo motor driver controls the nozzle vane position in accordance accordance with this signal and the actual nozzle vane position signal provided by the nozzle vane position sensor.
DC Motor
Turbo Pressure Sensor
Nozzle Vane Vane Position Sensor
Actual Nozzle Vane Position
Atmospheric Pressure Sensor
Nozzle Vane Vane Position Control
Crankshaft Position Sensor Injector
Engine ECU
Water Temp. Sensor
Target Nozzle Vane Position Signal
Turbo Motor Driver
Intake Air Temp. Sensor Turbocharger Turbocharger Control Status 271EG141
EG-166
ENGINE – 1KD-FTV AND 2KD-FTV ENGINES
Construction 1) General
Variable nozzle vane device is established on the turbine (exhaust) side, and consisted of a DC motor, nozzle vane position sensor, sensor, linkage, drive arm, unison ring, driven arms and nozzle vanes. DC Motor
Nozzle Vane Position Sensor Turbine Wheel
Linkage Nozzle Vane
Full-Close Stopper
Driven Arm Unison Ring
Drive Arm 271EG142
Service Tip
To control the nozzle vane position, the turbo motor driver renders the contact position of the linkage with the full-close stopper (thus fully closing the nozzle vane) as the zero point for the nozzle vane position sensor. If the turbocharger has been reinstalled or replaced, turn the ignition switch from ON to OFF once, and make sure that the linkage comes in contact with the full-close stopper. The full-close stopper position, which is adjusted at the factory at the time of shipment, is not serviceable in the field. For this reason, if the linkage does not come in contact with the full-close stopper during an inspection, the turbocharger assembly assembly must be replaced. Never attempt to loosen l oosen or tighten ti ghten the locknut of the full-close stopper because it will adversely affect the performance of the engine. For details, see the t he Hilux Repair Manual.
Linkage
Open
Full-Close Stopper
Close Lock Nut
271EG143
EG-167
ENGINE – 1KD-FTV AND 2KD-FTV ENGINES 2) Nozzle Vane Position Sensor
The nozzle vane position sensor consists of a Hall IC and a magnetic yoke that rotates in unison with the movement of the linkage that actuates the nozzle vane. The nozzle vane position sensor converts the changes in the magnetic flux that are caused by the rotation of the DC motor (hence, the rotation of the magnetic yoke) into electric signals, and outputs them to the turbo motor driver. The turbo motor driver determines the actual nozzle vane position from the electric signals in order to calculate the target nozzle vane position. Hall IC
4.5
Magnetic Yoke
Full Close
Output Voltage (V.)
Sensor Vane
0.5
Full Open
Nozzle Vane Vane Position Full Close
Full Open 271EG148
Sensor Vane 271EG147
System
Diagram Nozzle Vane Vane Position Sensor Magnetic Yoke
Magnet
VCX1 VSX1 Hall IC
Sensor Vane
E2X1
Turbo Motor Driver
Magnet 271EG149
EG-168
ENGINE – 1KD-FTV AND 2KD-FTV ENGINES
Operation 1) At Engine Low Speed Range
When the engine is running in a low speed range, the DC motor presses down the linkage by a signal from the turbo motor driver. The tip of the linkage rotates the unison ring counterclockwise through a drive arm. The unison ring contains a driven arm, which is placed through the cutout portion of the unison ring. This driven arm also moves in the direction of the rotation of the unison ring. The fulcrum of the driven arm is an axis that is integrated with the nozzle vane behind the plate. When the driven arm moves counterclockwise, the nozzle vane moves toward the closing direction. This results in increasing the velocity of the exhaust gas flowing to the turbine, as well as the speed of the turbine. t urbine. As a result, torque is improved when the engine is running at low speeds. DC Motor Nozzle Vane Linkage Linkage
Gas Flow
Fulcrum Unison Ring Plate
Drive Arm
Driven Arm
Cutout Portion Driven Arm 271EG144
2) At Engine Medium-to-High Speed Range
When the engine is running in a medium-to-high speed range, the DC motor pulls up the linkage by a signal from the turbo motor driver. With this, the driven arm moves clockwise and this opens the nozzle vane and holds the specified supercharging pressure. Thus, lowering the back pressure and improving the output and fuel consumption.
271EG145
ENGINE – 1KD-FTV AND 2KD-FTV ENGINES
EG-169
15. EGR Control System General The table below lists the differences between the EGR system on the 1KD-FTV and 2KD-FTV engines, as well as the differences differences in their control contents. Engine
Differences
1KD-FTV
A VSV (Vacuum Switching Valve) is provided for EGR valve close control.
2KD-FTV 2KD-FTV High Version
An EGR valve position sensor is provided for detecting the EGR valve position.
EGR Control for 1KD-FTV Engine By sensing the engine driving conditions, the engine ECU electrically operates both the E-VRV (for EGR valve control) and VSV (for EGR valve close), which controls the magnitude of vacuum introduced into diaphragm of EGR valve and intake shutter valve (throttle valve) opening position with intake shutter valve control motor and the amount of recirculating exhaust gas is regulated. EGR valve opening lift is controlled by modulated negative pressure. On the 1KD-FTV engine, the VSV (for EGR valve close) is activated when the EGR control is stopped, in order to introduce the atmospheric pressure to the EGR valve diaphragm and improve EGR valve closure response.
Intake Shutter Valve Position Sensor
Intake Shutter Valve
Intake Shutter Valve Control Motor
EGR Valve
Vacuum Pump
Vacuum Damper
Engine ECU
Atmospheric Pressure Sensor
Intake Manifold
Crankshaft Position Sensor Accelerator Pedal Position Sensor Water Temp. Sensor Turbo Pressure Sensor Intake Air Temp Sensor Air Flow Meter
E-VRV (for EGR Valve Control)
Engine
VSV (for EGR Valve Close) Exhaust Manifold
271EG150
EG-170
ENGINE – 1KD-FTV AND 2KD-FTV ENGINES
EGR Control for 2KD-FTV Engine By sensing the engine driving conditions and actual amount of EGR valve opening, the engine ECU electrically operates the E-VRV (for EGR valve control), which controls the magnitude of vacuum introduced into diaphragm of EGR valve and intake shutter valve (throttle valve) opening position with intake shutter valve control motor and the amount of recirculating exhaust gas is regulated. EGR valve opening lift is controlled by modulated negative pressure. pressure.
Intake Shutter Valve Position Sensor
Intake Shutter Valve
Intake Shutter Valve Control Motor EGR Valve Position Sensor Vacuum Damper
Vacuum Pump
Crankshaft Position Sensor
Engine ECU Intake Manifold
EGR Valve
Atmospheric Pressure Sensor
Accelerator Pedal Position Sensor Water Temp. Sensor Turbo Pressure Sensor Intake Air Temp Sensor
E-VRV (for EGR Valve Control)
Engine
Exhaust Manifold
271EG131
ENGINE – 1KD-FTV AND 2KD-FTV ENGINES
EG-171
16. Diagnosis The diagnosis system of the 1KD-FTV and 2KD-FTV engines uses the M-OBD (Multiplex On-Board Diagnosis). When the Engine ECU detects a malfunction, the engine ECU makes a diagnosis and memorizes the failed section. Furthermore, the check engine warning light in the combination meter illuminates or blinks to inform the driver. driver. The 2-digit DTCs (Diagnostic Trouble Codes) can be accessed by connecting the SST (09843-18040) to the DLC3 terminals TC and CG, and reading the blinking of the check engine warning light. By using the intelligent tester II, the 5-digit DTCs and ECU data can be read out. Moreover, the ACTIVE TEST can be used to drive the actuator by means of the intelligent tester II. The Engine ECU can output freeze-frame data to the intelligent tester II. This data is stored in the engine ECU at the very moment when the engine ECU has detected its last data of malfunction. All the DTCs have been made to correspond to the SAE controlled codes. Some of the t he DTCs have been further divided into smaller detection areas than in th e past, and new DTCs have been assigned to t hem. For details, see the Hilux Repair Manual.
Service Tip
To clear the DTC that is stored in the engine ECU, use a intelligent tester II or disconnect the battery terminal or remove the EFI fuse for 1 minute or longer.
17. Fail-Safe When a malfunction is detected by any of the sensors, there is a possibility of an engine or other malfunction occurring if the ECU were to continue to control the engine control system in the normal way. To prevent such a problem, the fail-safe function of the ECU either relies on the data stored in memory to allow the engine control system to continue operating, or stops the engine if a hazard is anticipated. For details, see the Hilux Repair Manual.