Re: OT- fuel mileage & fuel injection questions

On Fri, 23 Jun 2006 18:06:30 GMT, yourname <none@xxxxxxxx> wrote:

Dave Hinz wrote:
On Sat, 24 Jun 2006 01:21:22 +1000, Jordan <jwprincic@xxxxxxxxxxxxxxx> wrote:

lright, we determined that a turbo was a device that could be used to get useful work out of otherwise wasted energy, now we will discuss how that happens in more detail.

It is a common misconception that the exhaust turbine half of a turbo is driven purely by the kinetic energy of the exhaust smacking into it (like holding a kid's tow pinwheel behind your tailpipe) While the kinetic energy of the exhaust flow does contribute to the work performed by the turbo, the vast majority of the energy transferred comes from a different source.

Keep in mind the relationship between heat, volume, and pressure when we talk about gasses. High heat, high pressure, and low volume are all high energy states, low heat, low pressure, and large volumes are low energy states.

So our exhaust pulse exits the cylinder at high temperature and high pressure. It gets merged with other exhaust pulses, and enters the turbine inlet - a very small space. At this point, we have very high pressure and very high heat, so our gas has a very high energy level.

As it passes through the diffuser and into the turbine housing, it moves from a small space into a large one. Accordingly, it expands, cools, slows down, and dumps all that energy - into the turbine that we've so cleverly positioned in tho housing so that as the gas expands, it pushes against the turbine blades, causing it to rotate. Presto! We've just recovered some energy from the heat of the exhaust, that otherwise would have been lost.

This is a measurable effect: Stick an EGT upstream and downstream of the turbo, and you see a tremendous difference in temperature.

So, in real world terms, what does this tell us?

All else being equal, The amount of work that can be done across an exhaust turbine is determined by the pressure differential at the inlet and outlet (in English, raise the turbo inlet pressure, lower the outlet pressure, or both, and you make more power) Pressure is heat, heat is pressure.

Raising the inlet pressure is possible, but tough. Lowering the outlet pressure is easy - just bolt on a bigger, free flowing exhaust. I've seen a couple of posts from people who added aftermarket exhausts, who report "my turbo spools up faster now." Well, that's because by lowering the outlet pressure, you increased the pressure differential, and now the exhaust gas can expand more, and do more work. That increased work pushes harder on your turbo, and it spools up faster. You should also see less boost drop at redline, because if an exhaust system is flow-limited, once you pass the flow limit of the system, any additional gasses you try and force through it only raise the outlet pressure. Higher outlet pressure, lower pressure differential, less work, less boost.

[Note that the compressor side comes into play here too - that's another story]

Quote of the relavent part of that link, in case it doesn't work:



lright, we determined that a turbo was a device that could be used to
get useful work out of otherwise wasted energy, now we will discuss how
that happens in more detail.

It is a common misconception that the exhaust turbine half of a turbo is
driven purely by the kinetic energy of the exhaust smacking into it
(like holding a kid's tow pinwheel behind your tailpipe) While the
kinetic energy of the exhaust flow does contribute to the work performed
by the turbo, the vast majority of the energy transferred comes from a
different source.

Keep in mind the relationship between heat, volume, and pressure when we
talk about gasses. High heat, high pressure, and low volume are all high
energy states, low heat, low pressure, and large volumes are low energy
states.

So our exhaust pulse exits the cylinder at high temperature and high
pressure. It gets merged with other exhaust pulses, and enters the
turbine inlet - a very small space. At this point, we have very high
pressure and very high heat, so our gas has a very high energy level.

As it passes through the diffuser and into the turbine housing, it moves
from a small space into a large one. Accordingly, it expands, cools,
slows down, and dumps all that energy - into the turbine that we've so
cleverly positioned in tho housing so that as the gas expands, it pushes
against the turbine blades, causing it to rotate. Presto! We've just
recovered some energy from the heat of the exhaust, that otherwise would
have been lost.

This is a measurable effect: Stick an EGT upstream and downstream of the
turbo, and you see a tremendous difference in temperature.

So, in real world terms, what does this tell us?

All else being equal, The amount of work that can be done across an
exhaust turbine is determined by the pressure differential at the inlet
and outlet (in English, raise the turbo inlet pressure, lower the outlet
pressure, or both, and you make more power) Pressure is heat, heat is
pressure.

Raising the inlet pressure is possible, but tough. Lowering the outlet
pressure is easy - just bolt on a bigger, free flowing exhaust. I've
seen a couple of posts from people who added aftermarket exhausts, who
report "my turbo spools up faster now." Well, that's because by lowering
the outlet pressure, you increased the pressure differential, and now
the exhaust gas can expand more, and do more work. That increased work
pushes harder on your turbo, and it spools up faster. You should also
see less boost drop at redline, because if an exhaust system is
flow-limited, once you pass the flow limit of the system, any additional
gasses you try and force through it only raise the outlet pressure.
Higher outlet pressure, lower pressure differential, less work, less boost.

[Note that the compressor side comes into play here too - that's another
story]



An EXCELLENT explanation of how a turbo works.

--
Posted via a free Usenet account from http://www.teranews.com

.

Relevant Pages

  • Re: OT- fuel mileage & fuel injection questions
    ... lright, we determined that a turbo was a device that could be used to get useful work out of otherwise wasted energy, now we will discuss how that happens in more detail. ... Stick an EGT upstream and downstream of the turbo, and you see a tremendous difference in temperature. ... It is a common misconception that the exhaust turbine half of a turbo is driven purely by the kinetic energy of the exhaust smacking into it While the kinetic energy of the exhaust flow does contribute to the work performed by the turbo, the vast majority of the energy transferred comes from a different source. ... High heat, high pressure, and low volume are all high energy states, low heat, low pressure, and large volumes are low energy states. ...
    (rec.crafts.metalworking)
  • Re: Exhaust flow
    ... >> the exhaust valve opens before the end of the powerstroke. ... > pulses and give you essentially a static pressure drop. ... A turbo alone makes a very efficient ... > As such, the output is not pulse-free, but the pulse amplitude is reduced ...
    (uk.rec.cars.modifications)
  • Re: Colonizing the Galaxy in Eight Easy Steps
    ... >> pressure between the input and exhaust that allows work to be done. ... > reduces the pressure at exhaust to, say, 0.25 STP. ... > garden variety turbines where the energy input into ...
    (sci.space.policy)
  • Re: Colonizing the Galaxy in Eight Easy Steps
    ... > pressure between the input and exhaust that allows work to be done. ... reduces the pressure at exhaust to, say, 0.25 STP. ... Its the energy coming into the system that produces ...
    (sci.space.policy)
  • Re: Exhaust flow
    ... >>>atmospheric) on the exhaust side of the turbo, ... >>>difference across the turbo. ... > rpm to give boost at lower rpm than with stright-trough exhaust, ... How does it give less back pressure than no exhaust??? ...
    (uk.rec.cars.modifications)