EXHAUST MANIFOLD W/ TURBOCHARGER SYSTEM DESCRIPTION

This section should be used as a guide for troubleshooting when the turbocharger sub-assembly is suspected as the cause of a problem.


  1. OUTLINE OF TURBOCHARGER FAILURE


    1. State of Turbocharger Failure Repair:

      It is well known that turbocharger sub-assembly malfunctions cause many symptoms as shown below. However, the mechanisms resulting in these symptoms that indicate turbocharger sub-assembly malfunctions are not well understood. As a result, many unnecessary turbocharger sub-assembly replacements and other repairs are being performed due to lack of knowledge about the turbocharger sub-assembly and turbocharger sub-assembly failure. Therefore, knowing the facts regarding turbocharger sub-assembly malfunctions is useful for making effective repairs and saving time.

    2. Turbocharger Failure Classification

      Symptom Symptom Description See page
      Noise Whistling noise Continuous high pitch noise proportional to engine speed

      • "NOISE" listed below

      • Flowchart "Turbocharger Noise" Click here

      Whining noise Relatively low pitch noise compared to whistling noise
      Oil leak External oil leak Oil leak on surface of turbocharger visible from outside of turbocharger

      • "OIL LEAK AND WHITE SMOKE" listed below

      • Flowchart "Turbocharger Oil Leak and White Smoke" Click here

      Internal oil leak Oil leak from inside of bearing housing to inside of either compressor housing or turbine housing through seal ring
      White smoke Oil smoke Oil smoke is emitted from exhaust pipe
      Unburned fuel smoke Unburned fuel smoke is emitted from exhaust pipe
      Black smoke Black smoke is emitted from exhaust pipe

      • "BLACK SMOKE" listed below

      • Flowchart "Black Smoke Emitted" Click here

      Lack of power or hesitation Vehicle does not reach target speed

      • "LACK OF POWER AND HESITATION" listed below

      • Flowchart "Lack of Power or Hesitation" Click here

      Poor acceleration
      Shock during acceleration

      MIL turns on

      DTC

      		 P0046 Control Solenoid Circuit Range / Performance

      Diagnostic Trouble Code Chart Click here

      P0047 Boost Control "A" Circuit Low
      P0048 Boost Control "A" Circuit High
      P0299 Underboost
      P1251 Overboost Condition (Too High)
      P1264 VN Turbo Controller Malfunction
      P2563 Position Sensor "A" Circuit Range/Performance
      P2564 Position Sensor "A" Circuit Low
      P2565 Position Sensor "A" Circuit High
      P2588 Position Sensor "B" Circuit Low
      P2589 Position Sensor "B" Circuit High

      Tech Tips

      This table shows only typical problems related to the turbocharger sub-assembly.

  2. NOISE

    Description
    Probable Cause Probable Failed Component
    Turbine shaft imbalance Turbocharger
    Leakage from intake line Intake line

    Gear noise

    (Mistaken for turbocharger noise)

    • Gear inside engine

    • Transmission gear

    • Vacuum pump gear

    Tech Tips

    It is easy to confirm whether the turbocharger sub-assembly is the cause of the noise or not, and confirming this before inspecting the turbocharger sub-assembly or removing it from the engine is an effective way to reduce troubleshooting time.


    1. Connect the GTS to the DLC3.

    2. Start the engine and warm it up.

    3. Turn the GTS on.

    4. Enter the following menus: Powertrain / Engine / Active Test / Activate the VN Turbo Open.


      Powertrain > Engine and ECT > Active Test
      Tester Display
      Activate the VN Turbo Open

    5. Perform the Active Test and rev the engine up several times.

    6. Check whether the noise is reduced or not compared with the noise under the condition that the Active Test is not performed.

      Result
      Result Cause of Noise
      The noise is reduced (or disappears) Turbocharger
      The noise does not change Not turbocharger (other parts)

      Tech Tips

      Refer to the flowchart "Turbocharger Noise" Click here.

  3. OIL LEAK AND WHITE SMOKE

    Description
    Oil Leak Type Description Main Trouble Area

    Internal oil leak

    (White smoke)

    • Oil leak from bearing housing to either compressor housing (intake side) or turbine housing (exhaust side) through seal rings.

    • This type of oil leak is not visible from outside of turbocharger.

    • If oil leak occurs from turbine side seal, large amount of white smoke is emitted from exhaust pipe.

    • Compressor side seal ring

    • Turbine side seal ring

    • Clogging of oil drain

    • Shaft breakage

    • Shaft or bearing seizure

    • Compressor impeller damage
    External oil leak

    • Oil leak from inside of turbocharger to outside of turbocharger.

    • Includes oil leaks visible from outside of turbocharger.

    • FIPG sealing part

    • Oil pipe flange

    • Oil pipe union

    • Hose connection of intake pipe
    B003MEHC01
    *1 Compressor Housing *2 Seal Ring
    *3 Compressor Inlet *4 Compressor Impeller
    *5 Bearing Housing *6 Turbine Shaft
    *7 Oil Drain (Outlet) *8 FIPG Sealing Part
    *9 Turbine Housing *10 Turbine Wheel

    *a

    		 Internal oil leak to compressor housing

    *b

    		 Internal oil leak to turbine housing

    Tech Tips


    • Above illustration is an example.

    • When there is an internal oil leak, white smoke is emitted from the exhaust pipe and oil is consumed excessively. However, the cause of white smoke or excessive oil consumption can vary. Therefore, do not assume that the turbocharger sub-assembly is the cause of the failure when there is white smoke emission or excessive oil consumption.

    • When there is an external oil leak, the sources of the oil leak are limited to the points mentioned in the table above. If oil leaks from a FIPG sealing part, replace the turbocharger sub-assembly. If oil leaks from an oil pipe flange or a hose connection, do not replace the turbocharger sub-assembly, but confirm and repair the flange or hose.

    • Refer to the flowchart "Turbocharger Oil Leak and White Smoke" Click here.

  4. BLACK SMOKE


    1. Malfunctions are classified into 2 types as shown below.

      Description
      Malfunction Main Fault
      Intake air volume shortage Insufficient mass air flow due to, for example, excessively low boost pressure, which results in fuel injection volume being relatively excessive with respect to mass air flow.
      Excessive injection volume Excessive injection volume or incorrect injection timing due to fuel system trouble.

    2. Main Components Related to Black Smoke:

      Possible Faulty Component Main Fault
      Turbocharger Abnormally low boost pressure
      Intake system Leakage between turbocharger and intake manifold
      Fuel system

      • Excessive fuel injection volume

      • Incorrect fuel injection timing
      EGR valve Stuck or does not close completely
      Diesel throttle Stuck or does not move smoothly

      Tech Tips

      The components listed above are only the main ones. Not all the components potentially related to black smoke are listed. For details regarding the troubleshooting of black smoke, refer to the flowchart "Black Smoke Emitted" Click here.

    3. Relation between Turbocharger and Black Smoke:

      If the boost pressure is lower than normal due to a turbocharger sub-assembly failure, black smoke may occur due to a lack of mass air flow. However, abnormally low boost pressure can be caused by the failure of various components such as intake lines, the EGR valve, etc. Therefore, do not assume that the turbocharger is the cause of abnormally low boost pressure, but check all the components possibly related to abnormally low boost pressure. Components related to abnormal boost pressure are shown in a chart listed in the On-vehicle Inspection for Intake System Click here. For simple and effective troubleshooting, refer to the chart before starting troubleshooting.

  5. LACK OF POWER AND HESITATION


    1. Malfunctions are classified into 2 types as shown below.

      Description
      Malfunction Main Fault
      Intake air volume shortage Insufficient mass air flow due to, for example, excessively low boost pressure, which results in fuel injection volume being restricted.
      Abnormal injection volume Abnormal injection volume or timing due to fuel system trouble.

    2. Main Components Related to Lack of Power and Hesitation:

      Possible Faulty Component Main Fault
      Turbocharger

      • Abnormal boost pressure

      • VN does not move smoothly
      Intake system

      • Leakage between turbocharger and intake manifold

      • Clogging or blockage of intake line
      Fuel system

      • Abnormal injection volume

      • Incorrect fuel injection timing
      EGR valve Stuck or does not close completely
      Diesel throttle Stuck or does not move smoothly
      Exhaust system Clogging of exhaust line

      Tech Tips


      • The components listed above are only the main ones. Not all the components potentially related to lack of power and hesitation are listed. For details regarding the troubleshooting of lack of power and hesitation, refer to the flowchart "Lack of Power or Hesitation" Click here.

      • If obvious malfunction (lack of power) has not been reproduced, perform test driving another vehicle, which is the same model and has the same engine, and compare the engine conditions and performance. If a great difference does not present in engine performance, explain to the customer that lack of power the customer mentioned is not abnormal.

    3. Relation between Turbocharger and Abnormal Boost Pressure:

      If the boost pressure is lower than normal due to a turbocharger sub-assembly failure, lack of power could occur due to an intake air volume shortage. However, abnormal boost pressure can be caused by the failure of various components such as intake lines, the EGR valve, etc. Therefore, do not assume that the turbocharger sub-assembly is the cause of abnormal boost pressure, but check all the components possibly related to abnormal boost pressure. Components related to abnormal boost pressure are shown in a chart listed in the On-vehicle Inspection for Intake System Click here. For simple and effective troubleshooting, refer to the chart before starting troubleshooting.

  6. MIL TURNS ON

    If a DTC related to a turbocharger sub-assembly malfunction is stored, refer to the troubleshooting section for each DTC Click here.

  7. BRIEF OUTLINE OF TURBOCHARGER OPERATION AND CONSTRUCTION


    1. A turbocharger is a component used to supply a larger air volume to the cylinders by recovering exhaust gas energy using a turbine coaxially connected to a compressor.

    2. Principle of Turbocharging:

      Boost pressure is proportional to turbocharger speed, because the intake air is accelerated by centrifugal force generated by the rotation of the compressor and the increased kinetic energy, i.e. the velocity of the intake air, is converted to pressure energy by the diffuser located around the outlet of the compressor impeller. The compressor is driven by the turbine connected coaxially by the turbine shaft. The turbine is driven by exhaust gas energy. Therefore, when the turbocharger begins boosting the intake air, a larger air volume is supplied to the cylinders and more fuel can be injected. As a result, more exhaust energy will be available and the turbocharger boost increases.

      B003MFGC02
      *1 Compressor *2 Turbine
      *3 Air Cleaner *4 Exhaust Manifold
      *5 Intake Manifold *6 Intercooler
      *7 Diffuser *8 Compressor

      *a

      		 See HINT below

      *b

      		 Intake air flow

      Tech Tips


      • Above illustration is an example.

      • *a: If sufficient exhaust gas energy is not available, the turbocharger cannot generate the required boost pressure even when the turbocharger does not have a malfunction.

      • Considering the fact that the turbocharger is driven by exhaust gas energy, if sufficient exhaust gas is not available due to abnormal injection volume, etc., the required boost pressure will not be available even when the turbocharger does not have a malfunction. Therefore, when boost pressure is abnormally low, checking all the related components using the correct troubleshooting procedure is necessary to perform repairs simply and effectively.

    3. Boost Pressure Control:

      The amount of energy the turbine can obtain from the exhaust gas is proportional to the expansion ratio, which is defined as the ratio of the turbine inlet exhaust gas pressure to the pressure at the turbine outlet. To control boost pressure, a Variable Nozzle (VN) is used just upstream of the turbine wheel inlet, and controls the expansion ratio. If the VN is closed, the gap between neighboring vanes is narrowed and the turbine inlet exhaust gas pressure, and correspondingly the expansion ratio, increases. Therefore, when the VN is closed, the turbine receives more energy, and the turbine speed and boost pressure increase. If the VN is opened, the turbine inlet exhaust gas pressure decreases and the turbine speed and boost pressure decrease.

      B003KVXC05
      *1 VN (Variable Nozzle) *2 Turbine Wheel
      *3 Narrow Gap *4 Wide Gap

      *a

      		 VN Closed

      *b

      		 VN Opened

      *c

      		 Exhaust Gas Flow - -

      Tech Tips


      • Above illustration is an example.

      • If the VN becomes stuck open, the necessary boost pressure will not be available. If the VN becomes stuck closed, overboost will occur.

    4. Mechanical Construction of Turbocharger:

      B003M86C01
      *1 VN Actuator (DC Motor) *2 VN Actuating Rod
      *3 Bearing Housing *4 Turbine Shaft
      *5 Turbine Side Seal Ring *6 Turbine Housing
      *7 Turbine Wheel *8 Thrust Bearing
      *9 Compressor Side Seal Ring *10 Compressor Housing
      *11 Compressor Impeller *12 Radial Bearing
      *13 Oil Drain *14 VN (Variable Nozzle)

      *a

      		 See HINT below

      *b

      		 See HINT below
      B003R2S Exhaust Gas Flow B003LF2 Intake Air Flow

      Tech Tips


      • Above illustration is an example.

      • *a: A certain amount of oil mist from PCV gas is contained in the intake air. Therefore, a certain amount of oil at the inlet of the compressor is normal, and is not an oil leak.

      • *b: The seal rings are C-shaped rings just like piston rings, and have a gap. Therefore, complete sealing is impossible by the seal rings alone. The oil is sealed in with the aid of the boost pressure in the compressor housing, and the exhaust gas pressure in the turbine housing. These pressures prevent oil from exiting the bearing housing through the gap of the seal rings. Therefore, if the turbine shaft is inclined from the horizontal, oil may flow out through the gap of a seal ring. This should not be interpreted as an oil leak due to seal ring failure.