How Turbochargers Work
When people talk about race cars or high-performance sports cars, the topic of turbochargers usually comes up. Turbochargers also appear on large diesel engines. A turbo can significantly boost an engine's horsepower without significantly increasing its weight, which is the huge benefit that makes turbos so popular!
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In this article, we'll learn how a turbocharger increases the power output of an engine while surviving extreme operating conditions. We'll also learn how wastegates, ceramic turbine blades and ball bearings help turbochargers do their job even better!
What Is a Turbocharger?
Turbochargers are a
type of forced induction system. They compress
the air flowing into the engine (see How Car
Engines Work for a description of airflow in a normal
engine). The advantage of compressing the air is that it lets
the engine squeeze more air into a cylinder, and more air
means that more fuel can be added. Therefore, you get more
power from each explosion in each cylinder. A turbocharged
engine produces more power overall than the same engine
without the charging. This can significantly improve the
power-to-weight ratio for the engine (see
How
Horsepower Works for details).
In order to achieve this boost, the turbocharger uses the exhaust flow from the engine to spin a turbine, which in turn spins an air pump. The turbine in the turbocharger spins at speeds of up to 150,000 rotations per minute (rpm) -- that's about 30 times faster than most car engines can go. And since it is hooked up to the exhaust, the temperatures in the turbine are also very high.
Basics
One of the surest ways to get more
power out of an engine is to increase the amount of air and
fuel that it can burn. One way to do this is to add cylinders
or make the current cylinders bigger. Sometimes these changes
may not be feasible -- a turbo can be a simpler, more compact
way to add power, especially for an aftermarket accessory.
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Turbochargers allow an engine to burn more fuel and air by packing more into the existing cylinders. The typical boost provided by a turbocharger is 6 to 8 pounds per square inch (psi). Since normal atmospheric pressure is 14.7 psi at sea level, you can see that you are getting about 50 percent more air into the engine. Therefore, you would expect to get 50 percent more power. It's not perfectly efficient, so you might get a 30- to 40-percent improvement instead.
One cause of the inefficiency comes from the fact that the power to spin the turbine is not free. Having a turbine in the exhaust flow increases the restriction in the exhaust. This means that on the exhaust stroke, the engine has to push against a higher back-pressure. This subtracts a little bit of power from the cylinders that are firing at the same time.
Turbos on High
A turbocharger helps at
high altitudes, where the air is less dense. Normal
engines will experience reduced power at high altitudes
because for each stroke of the piston, the engine will get a
smaller mass of air. A turbocharged engine may also have
reduced power, but the reduction will be less dramatic because
the thinner air is easier for the turbocharger to pump.
Older cars with carburetors automatically increase the fuel rate to match the increased airflow going into the cylinders. Modern cars with fuel injection will also do this to a point. The fuel-injection system relies on oxygen sensors in the exhaust to determine if the air-to-fuel ratio is correct, so these systems will automatically increase the fuel flow if a turbo is added.
If a turbocharger with too much boost is added to a fuel-injected car, the system may not provide enough fuel -- either the software programmed into the controller will not allow it, or the pump and injectors are not capable of supplying it. In this case, other modifications will have to be made to get the maximum benefit from the turbocharger.
How It Works
The turbocharger is bolted to
the exhaust manifold of the engine. The exhaust from
the cylinders spins the turbine, which works like a gas turbine
engine. The turbine is connected by a shaft to the
compressor, which is located between the air filter and
the intake manifold. The compressor pressurizes the air going
into the pistons.
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The exhaust from the cylinders passes through the turbine blades, causing the turbine to spin. The more exhaust that goes through the blades, the faster they spin.
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On the other end of the shaft that the turbine is attached to, the compressor pumps air into the cylinders. The compressor is a type of centrifugal pump -- it draws air in at the center of its blades and flings it outward as it spins.
In order to handle speeds of up to 150,000 rpm, the turbine shaft has to be supported very carefully. Most bearings would explode at speeds like this, so most turbochargers use a fluid bearing. This type of bearing supports the shaft on a thin layer of oil that is constantly pumped around the shaft. This serves two purposes: It cools the shaft and some of the other turbocharger parts, and it allows the shaft to spin without much friction.
There are many tradeoffs involved in designing a turbocharger for an engine. In the next section, we'll look at some of these compromises and see how they affect performance.
Design Considerations
Before we talk about
the design tradeoffs, we need to talk about some of the
possible problems with turbochargers that the designers must
take into account.
Too Much Boost
With
air being pumped into the cylinders under pressure by the
turbocharger, and then being further compressed by the piston
(see How
Car Engines Work for a demonstration), there is more
danger of knock.
Knocking happens because as you compress air, the
temperature of the air increases. The temperature may increase
enough to ignite the fuel before the spark
plug fires. Cars with turbochargers often need to run on
higher octane
fuel to avoid knock. If the boost pressure is really high, the
compression ratio of the engine may have to be reduced to
avoid knocking.
Turbo Lag
One of the
main problems with turbochargers is that they do not provide
an immediate power boost when you step on the gas. It takes a
second for the turbine to get up to speed before boost is
produced. This results in a feeling of lag when you step on
the gas, and then the car lunges ahead when the turbo gets
moving.
One way to decrease turbo lag is to reduce the inertia of the rotating parts, mainly by reducing their weight. This allows the turbine and compressor to accelerate quickly, and start providing boost earlier.
Small vs. Large
Turbocharger
One sure way to reduce the inertia of
the turbine and compressor is to make the turbocharger
smaller. A small turbocharger will provide boost more quickly
and at lower engine speeds, but may not be able to provide
much boost at higher engine speeds when a really large volume
of air is going into the engine. It is also in danger of
spinning too quickly at higher engine speeds, when lots of
exhaust is passing through the turbine.
A large turbocharger can provide lots of boost at high engine speeds, but may have bad turbo lag because of how long it takes to accelerate its heavier turbine and compressor.
In the next section, we'll take a look at some of the tricks used to overcome these challenges.
Optional Turbo Features
The Wastegate
Most
automotive turbochargers have a wastegate, which allows
the use of a smaller turbocharger to reduce lag while
preventing it from spinning too quickly at high engine speeds.
The wastegate is a valve that allows the exhaust to bypass the
turbine blades. The wastegate senses the boost pressure. If
the pressure gets too high, it could be an indicator that the
turbine is spinning too quickly, so the wastegate bypasses
some of the exhaust around the turbine blades, allowing the
blades to slow down.
Ball Bearings
Some
turbochargers use ball bearings instead of fluid
bearings to support the turbine shaft. But these are not your
regular ball
bearings -- they are super-precise bearings made of
advanced materials to handle the speeds and temperatures of
the turbocharger. They allow the turbine shaft to spin with
less friction than the fluid bearings used in most
turbochargers. They also allow a slightly smaller, lighter
shaft to be used. This helps the turbocharger accelerate more
quickly, further reducing turbo lag.
Ceramic Turbine
Blades
Ceramic turbine blades are lighter
than the steel blades used in most turbochargers. Again, this
allows the turbine to spin up to speed faster, which reduces
turbo lag.
Sequential
Turbochargers
Some engines use two
turbochargers of different sizes. The smaller one spins up
to speed very quickly, reducing lag, while the bigger one
takes over at higher engine speeds to provide more boost.
Another optional feature is the intercooler. We'll take a look at one on the next page.
Intercoolers
When air is compressed, it
heats up; and when air heats up, it expands. So some of the
pressure increase from a turbocharger is the result of heating
the air before it goes into the engine. In order to increase
the power of the engine, the goal is to get more air molecules
into the cylinder, not necessarily more air pressure.
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An intercooler or charge air cooler is an additional component that looks something like a radiator, except air passes through the inside as well as the outside of the intercooler. The intake air passes through sealed passageways inside the cooler, while cooler air from outside is blown across fins by the engine cooling fan.
The intercooler further increases the power of the engine
by cooling the pressurized air coming out of the compressor
before it goes into the engine. This means that if the
turbocharger is operating at a boost of 7 psi, the intercooled
system will put in 7 psi of cooler air, which is denser and
contains more air molecules than warmer air.
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