Normal Operation and Fault Conditions
The engine cooling system is a closed system providing for coolant expansion and contraction as well as changes in pressure as coolant warms and cools with engine operation. Various gaskets, seals, hoses and clamps contain coolant within the cooling system and keep other fluids and contaminants from entering the cooling system.
Coolant loss can be attributed to external or internal leaks anywhere within the cooling system, including
- Coolant hoses or tubes
- Hose clamps
- Thermostat housing
- Thermostat housing O-ring seals
- Coolant inlet connection
- Coolant inlet connection O-ring seal
- Coolant inlet pipe
- Coolant inlet pipe O-ring seals
- Coolant pump gasket
- Radiator
- Pressure relief cap
- Coolant pump
- Oil cooler (may leak internally or externally) (if equipped)
- Heater core
- Engine gaskets (may leak internally or externally)
- Degas bottle
- Cylinder block core plugs
- Cylinder head core plugs
- Block heater (if equipped)
- Turbocharger - 2.0L GTDI
REFER to System Diagram .
The engine cooling system maintains the engine temperature during operation. Correct coolant flow through the engine, radiator and remainder of cooling system passages and components is essential to maintaining a correct engine temperature.
Engine coolant flows primarily from the engine to the radiator circuit and back to the coolant pump. Coolant is sent from the coolant pump through the engine block and cylinder heads. A separate circuit from the engine also feeds the heater core with coolant. The coolant pump circulates the coolant. For 2.0L GTDI, the coolant pump operated by engine rotation through a pulley driven by the accessory drive belt. For 3.5L Ti-VCT , the coolant pump is operated by engine rotation through a sprocket driven by the camshaft timing chain. The coolant thermostat is a control valve actuated by coolant temperature. When the thermostat is closed, coolant flow bypasses the radiator circuit and returns to the coolant pump. When the thermostat is opened, coolant flows through the radiator circuit to transfer engine-generated heat to the outside air.
Engine overheating generally occurs when there is a disruption in the ability to control either coolant flow at the correct rate, the inability to transfer heat from the engine through the coolant (including low coolant) or an inability to transfer engine-generated heat to the outside air through the radiator. Engine overheating can be attributed to
- Low coolant level
- External engine coolant leak
- Airlock in system
- Pressure relief cap installation
- Restricted airflow through the A/C condenser/radiator
- Internal engine coolant leak
- Coolant condition/concentration
- Accessory drive components
- Non- OEM engine enhancement components
- Electric cooling fan
- Radiator
- Thermostat
- Temperature gauge
- Coolant pump
- Coolant flow restriction
REFER to System Diagram .
| DTC | Description | Fault Trigger Conditions |
|---|---|---|
| P0217 | Engine Coolant Overtemperature Condition | Indicates an engine overheat condition was sensed by the CHT sensor or the ECT sensor. |
| P1285 | Cylinder Head Overtemperature Condition | Indicates an engine overheat condition was sensed by the CHT sensor or the ECT sensor. |
| P1299 | Cylinder Head Overtemperature Protection Active | Indicates an engine overheat condition was detected by the CHT sensor or the ECT sensor. A failure mode effects management strategy called fail-safe cooling was activated to cool the engine. |
DTC FAULT TRIGGER CONDITIONS
The engine cooling system maintains engine temperature during operation. Correct coolant flow through the engine, radiator and remainder of cooling system passages and components is essential to maintaining a correct engine temperature.
Engine coolant flows primarily from the engine to the radiator circuit and back to the coolant pump. Coolant is sent from the coolant pump through the engine block and cylinder heads. A separate circuit from the engine also feeds the heater core with coolant. The coolant pump circulates the coolant. For 2.0L GTDI, the coolant pump is operated by engine rotation through a pulley driven by the accessory drive belt. For 3.5L Ti-VCT , the coolant pump is operated by engine rotation through a sprocket driven by the camshaft timing chain. The coolant thermostat is a control valve actuated by coolant temperature. When the thermostat is closed, coolant flow bypasses the radiator circuit and returns to the coolant pump. When the thermostat is opened, coolant flows through the radiator circuit in order to transfer engine generated heat to the outside air.
Concerns of engine inability to reach normal operating temperature typically occur when the rate of coolant flow through some coolant circuits (radiator, heater core) is more than expected given the conditions, or when the electric cooling fan operates all of the time. Heat is not allowed to build in the engine because a heat exchanger is removing too much heat, including the radiator, heater core and oil cooler. In addition, perceived concerns that the engine does not reach normal operating temperature can be related to a low coolant level or trapped air which does not allow for hot coolant to be available at the heater core, an inoperative climate control system, or for concerns perceived or related to an incorrect engine temperature gauge indication. The engine not reaching normal operating temperature can be attributed to
- Low coolant level
- Thermostat
- Engine cooling fan always on
- Temperature gauge
Engine Cooling
| DTC | Description | Fault Trigger Conditions |
|---|---|---|
| P0125 | Insufficient Coolant Temp for Closed Loop Fuel Control | Indicates the CHT sensor or ECT sensor has not achieved the required temperature level to enter closed loop operating conditions within a specified amount of time after starting the engine. |
| P0128 | Coolant Thermostat (Coolant Temp Below Thermostat Regulating Temperature) | Indicates that the thermostat monitor has not achieved the required engine operating temperature within a specified amount of time after starting the engine. |
DTC FAULT TRIGGER CONDITIONS