XK (X150) V8-4.2L (2008)
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Variable Valve Timing Solenoid: Description and Operation
Electronic Engine Controls
Variable Valve Control (VVC)
Variable valve timing is used on the V8 engine to enhance low and high speed engine performance and idle speed quality.
For each inlet camshaft the VVC system comprises:
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VVC unit
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Valve timing solenoid
The VVC system alters the phase of the intake valves relative to the fixed timing of the exhaust valves, to alter:
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The mass of air flow to the cylinders.
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The engine torque response.
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Emissions.
The VVC unit uses a vane type device to control the camshaft angle. The system operates over a range of 48 degrees and is advanced or retarded to its
optimum position within this range.
The VVC system is controlled by the ECM based on engine load and speed along with engine oil temperature to calculate the appropriate camshaft
position.
The VVC system provides the following advantages:
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Reduced engine emissions and improved fuel consumption which in turn improves the engines internal EGR effect over a wider operating range.
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Enhanced full load torque characteristics.
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Improved fuel economy through optimized torque over the engine speed range.
Variable Valve Timing Unit
The VVC unit is a hydraulic actuator mounted on the end of the inlet camshaft. The unit advances or retards the camshaft timing to alter the camshaft to
crankshaft phase. The ECM controls the VVC timing unit via a oil control solenoid. The oil control solenoid routes oil pressure to the advance or retard
chambers either side of the vanes within the VVC unit.
The VVC unit is driven by the primary drive chain and rotates relative to the exhaust camshaft. When the ECM requests a retard in camshaft timing the
oil control solenoid is energized which moves the shuttle valve in the solenoid to the relevant position allowing oil pressure to flow out of the advance
chambers in the VVC unit whilst simultaneously allowing oil pressure into the retard chambers.
The ECM controls the advancing and retarding of the VVC unit based on engine load and speed. The ECM sends an energize signal to the oil control
solenoid until the desired VVC position is achieved. When the desired VVC position is reached, the energizing signal is reduced to hold the oil control
solenoid position and consequently desired VVC position. This function is under closed loop control and the ECM can sense any variance in shuttle
valve oil pressure via the camshaft position sensor and can adjust the energizing signal to maintain the shuttle valve hold position.
VVC operation can be affected by engine oil temperature and properties. At very low oil temperatures the movement of the VVC mechanism will be
slow due to the high viscosity of the oil. While at high oil temperatures the low oil viscosity may impair the VVC operation at low oil pressures. The oil
pump has the capacity to cope with these variations in oil pressure while an oil temperature sensor is monitored by the ECM to provide oil temperature
feedback. At extremely high oil temperatures the ECM may limit the amount of VVC advance in order to prevent the engine from stalling when returning
to idle speed.
VVC does not operate when engine oil pressure is below 1.25 bar. This is because there is insufficient pressure to release the VVC units internal stopper
pin. This occurs when the engine is shut down and the VVC unit has returned to the retarded position. The stopper pin locks the VVC unit to the
camshaft to ensure camshaft stability during the next start up.
Valve Control Solenoid
