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An understanding of the physics that allows flight
must be built on a foundation of understanding of the "first
principles" involved. I have found recent postings about pressure and
atomization a little confusing so here is a modest attempt to clarify
things.
Almost all pressure gauges measure the difference in forces present on
two surfaces. The force on the surface is the result of gas or liquid
molecule's atomic forces colliding with that surfaces atoms' atomic
forces. The resultant normal net differential force is measured directly, in the case of
a bellows (altimeter) movement, or inferred by the presence of gauge
element strain in the case of diaphragm or Burdon Tube elements.
Almost all pressure gages measure strain (movement) either mechanically
(levers and gears) or electrically (resistive strain gauge).
Differential gauges are divided into three classes:
1) Absolute Pressure gauges that measure a pressure referenced to a
vacuum. (Altimeter and MAP)
2) Differential Pressure gauges that measure the pressure difference
between two ports. (Cabin differential pressure)
3) Gauge Pressure gauges that measure a pressure referenced to the
local ambient pressure. (Fuel, oil and hydraulic pressure)
Differential Pressure gauges can be configured for either Absolute
Pressure measurements by connecting the reference port to vacuum or
configured for Gauge Pressure measurements by leaving the reference
port open to the environment.
Almost all pressure gauges fall into one of these categories. There are
other methods of measuring pressure or inferring pressure from density
using lasers, ionization, drag, resonance and even acoustics.
Atomization is the process where large droplets of fluid are divided
into smaller droplets. The smaller the droplet the larger the ratio of
surface area to volume and, in the case of a fuel air mixture, the
faster the droplet will vaporize.
Pressure does not cause atomization. Shear causes atomization. Shear
occurs at the interface of two slipstreams of different velocity.
Picture a high wind over a lake, producing whitecaps and atomizing the
water into a fine mist. In the case of an intake runner, injecting fuel
near the wall of the tube (just above the boundary layer) produces
better atomization than if the same injector was located in the center
of the tube. High performance carburetors have a secondary coaxial
venturi and the fuel is injected at its periphery.
Combustion requires fuel vapor (not liquid) and atomization encourages
vaporization so the more atomization the better, right? Wrong.
Vaporization requires heat, reducing the temperature and increasing the
density of the fuel air charge. For best volumetric performance the
fuel should vaporize after it enters the combustion chamber but before
the intake valve closes. The charge is cooled by the vaporization,
increasing its density and providing more
"room" for additional charge. This timing
requires fuel droplets of a specific size range, not too big or small
so more atomization is not better, after a point.
Does any of this matter in our aircraft engines? Not very much,
really. Our aircraft engines are big and slow and use (on injected
engines) continuous injection. In high performance fuel injected racing
engines, fuel injection begins at the start of the intake stroke and
stops at the end. This produces a relatively homogeneous mixture of
fuel and air entering the cylinder. On our aircraft fuel injected
engines all the injectors are flowing all the time. The fuel
accumulates in the intake tube for 75% of the time and is then gulped
into the cylinder in one very rich slug followed by a very lean
mixture. Fortunately, because aircraft engines operate at relatively
slow speeds, there is lots of time to vaporize the fuel. As George
Braly will likely tell you, consistency from cylinder to cylinder and
from cycle to cycle has a greater effect on performance and smoothness
than fuel droplet size.
Wishing all of you clear and safe skies in the new year.
Brent Regan
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