Understanding Toyota's VVT-i System

by: JasonLancaster
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Word Count: 650

Any mechanic or automotive enthusiast can tell you that an engine is essentially a large air pump. The more an engine can suck in air to mix with fuel, the more it can create power through combustion. Thus, the more efficiently an engine removes exhaust gases from the cylinders, the better it can manage that power. The key to a strong, healthy engine is adequate air from one end to another.

Many different things can affect air flow in a motor, but the primary control over the volumes of air entering a cylinder, and exhaust leaving it, comes from the valves in the cylinder head. The intake valves open immediately before combustion to allow air to flow in and combine with the fuel. After this mixture has been ignited, the exhaust valves open and suck out the resulting gases. Valve timing is controlled by the camshaft, which is a rotating shaft with lobes pushing up on the valves to open them, then drop them closed again.

How long these valves remain open, and at what point in the combustion cycle, can have a big impact on the drivability and power generated by an engine. For instance, if you want to have a really fast car, like a race car, you'll want the engine to produce a lot of power at high RPMs. You can adjust the camshaft to perform well at higher RPMs. This will result in poor performance at low RPMs, but that's OK with a race car. Conversely, if you want a lot of low-end torque - which is great for towing - you need to adjust the camshaft to perform well at low RPMs. This, of course, will hurt high RPM performance.

Unfortunately for street vehicles, they need to be a compromise between reliability, fuel efficiency and power. Vehicles like race cars, which perform within a specific range of RPM, can afford to have poor performance outside their optimal RPM, in return for large amounts of power and high performance at their ideal RPM range. Street vehicles, however, need to function over a large range of RPMs. It would be no good if your street car stalled at every traffic light or ran out of steam whenever you tried to take the highway! Regular vehicles need to use a camshaft design that provides adequate power in the most often used range of RPMs.

These compromise camshafts aren't terribly efficient. Because they try to do so many things - from accelerating your car from a dead stop to providing performance at highway speeds, and everything in between - they don't do any one of them very well. This means that your engine burns too much fuel most of the time, while also underperforming.

Automakers have addressed this concern with something called "variable valve timing" (VVT). The Toyota Tundra's i-Force 5.7L V8, Toyota's newest VVT-i engine, has the ability to vary the timing of the valves in relation to engine speed. It does this by using engine oil pressure to move the camshaft slightly, so that more aggressive lobe designs are used when the engine is running at a higher rpm. By doing this, the i-Force V8 is able to run a camshaft profile that provides good fuel efficiency in every day driving, but is still able to churn out gobs of power when the pedal is pressed to the floor.

The Tundra's dual VVT-i goes one step further by allowing the exhaust and intake valves to open simultaneously at extremely high RPMs, to scavenge airflow as much as possible. This results in a V8 engine that can produce 381 horsepower at 5600 rpm, and 401 lb-ft of torque at as low as 3600 rpm - while still getting a respectable 20 miles per gallon on the highway with the 2 wheel drive models. And what's best is, the Toyota variable valve timing system gives you killer horsepower without killing you at the gas pump.

About the Author

Author Jason Lancaster is the editor of TundraHeadquarters.com, a website with info, news, and reviews of Toyota Tundra accessories and Tundra parts.  

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