Fluid Dynamics involves the interactions
between an object and a surrounding fluid, a
liquid, or a gas.
Fluid dynamics play a major role in the devlopment of
thrust
in a
gas turbine engine,
and in the generation of
aerodynamic drag
for flight within the atmosphere.
To better understand these
interactions, we need to know some things about gases.
Characteristics of Gases
All matter is made from atoms with the configuration of the atom
(number of protons, number of neutrons ..) determining the kind of
matter present (oxygen, lead, silver, neon ...). Individual atoms can
combine with other atoms to form molecules. Oxygen and
nitrogen, which are the major components of air on
Earth,
occur in nature as
diatomic (2 atom) molecules.
The atmosphere of Mars
is mostly composed of carbon dioxide, a molecule with one carbon atom
and two oxygen atoms.
Under normal conditions, matter
exists as either
a solid, a liquid, or a gas.
Atmospheres are composed of gases. In
any gas, we have a very large number of molecules that are only
weakly attracted to each other and are free to move about in space.
When studying gases, we can investigate the motions and interactions
of individual molecules, or we can investigate the large scale action
of the gas as a whole. Scientists refer to the large scale motion of
the gas as the macro scale and the individual molecular
motions as the micro scale. Some phenomenon are easier to
understand and explain based on the macro scale, while other
phenomenon are more easily explained on the micro scale. Macro scale
investigations are based on things that we
can easily observe
and measure. But micro scale investigations are based on rather
simple theories because we cannot actually
observe an individual gas molecule in motion. Macro scale and micro
scale investigations are just two views of the same thing.
Large Scale Motion of a Gas--Macro Scale
The atmosphere is treated as a uniform gas with properties that are averaged
from all the individual components (oxygen, nitrogen, water
vapor...). On the macro scale, we are dealing with large scale
effects that we can measure, such as the gas
velocity, the pressure exerted on the
surroundings, or the temperature of the
gas. A gas does not have a fixed shape or size but will expand to
fill any container. Because the molecules are free to move about in a
gas, the mass of the gas is normally characterized
by the density.
Density is the mass per volume of a substance.
On the macro scale, the properties of the gas can change with
altitude and depend on
the thermodynamic
state of the gas. The state of the gas can be changed by
thermodynamic processes.
Mathematical equations
have been developed which describe the relations of the
pressure, density, temperature,
and velocity of a moving gas.
The equations are very hard to solve in general. Some
simplified versions
of the equations can be solved to model certain fluids problems.
Individual Molecular Motion of a Gas--Micro Scale
On the micro scale, a gas is modeled by the
kinetic theory.
The model assumes that the molecules are very small relative
to the distance between molecules. The molecules are in constant,
random motion and frequently collide with each other and with the
walls of any container. The molecules have the standard physical
properties of mass, momentum, and energy. And these properties are
related to the macro properties of density, pressure, and
temperature. The interactions of the molecules introduce some other
properties that we normally do not encounter when dealing with
solids. In a solid, the location of the molecules relative to each
other remains almost constant. But in a fluid, the molecules can move
around and interact with each other and with their surroundings in
different ways. As mentioned above, there is always a random
component of molecular motion. But the entire fluid can be made to
move as well in an ordered motion. As the molecules move, the
properties of the fluid move as well. If the properties are
transported by the random motion, the process is called
diffusion. (An example of diffusion is the spread of an odor
in a perfectly still room). If the properties are transported by the
ordered motion, the process is called convection. An example
of convection is a blast of cold weather brought down from Canada.
If the flow of a gas produces a net angular momentum, we say the flow
is rotational. No net angular momentum in the fluid is called
irrotational.
Viscosity
As an object moves through a gas, the viscosity (stickiness)
of the gas becomes very important. Gas molecules stick to any
surface, creating a layer of air near the surface, called a
boundary layer
that, in effect, changes the shape of the
object. To make things more confusing, the boundary layer may lift
off or "separate" from the body and create an effective shape much
different from the physical shape of an object. And to make it even
more confusing, the flow conditions in and near the boundary layer
are often unsteady (changing in time) and may become
randomly turbulent. The boundary layer is
very important in determining both the drag
and lift of an object.
Compressibility
As an object moves through a gas, the compressibility of the
gas also becomes important. Gas molecules move around an object as it
passes through. If the object passes at a low speed (typically less
than 200 mph), the density of the fluid
remains constant. But for high speeds, some
of the energy of the object goes into compressing the fluid, moving
the molecules closer together and changing the gas density, which
alters the amount of the resulting force on the object. This effect
is more important as speed increases. Near and beyond the speed of
sound (about 700 mph),
shock waves
are produced that affect both the
lift and drag of an object.
Activities:
Guided Tours
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Standard Atmosphere Model:
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Gas Statics:
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