Everything about Boussinesq Approximation Buoyancy totally explained
In
fluid dynamics, the
Boussinesq approximation (named for
Joseph Valentin Boussinesq) is used in the field of buoyancy-driven flow. It states that density differences are sufficiently small to be neglected, except where they appear in terms multiplied by
g, the acceleration due to gravity. The essence of the
Boussinesq approximation is that the difference in
inertia is negligible but gravity is sufficiently strong to make the specific
weight appreciably different between the two fluids.
Sound waves are impossible/neglected when the Boussinesq approximation is used since sound waves move via density variations.
Boussinesq flows are common in nature (such as
atmospheric fronts, oceanic circulation,
katabatic winds), industry (
dense gas dispersion, fume cupboard ventilation), and the built environment (natural ventilation,
central heating). The approximation is extremely accurate for many such flows, and makes the mathematics and physics simpler.
The approximation's advantage arises because when
considering a flow of, say, warm and cold water of density
and
one needs only consider a
single density
: the difference
is negligible.
Dimensional analysis shows that, under these circumstances, the only sensible
way that acceleration due to gravity
g should enter into the equations of motion is in the reduced gravity
where
»
(Note that the denominator may be either density without affecting the result because the change would be of order
). The most generally used
dimensionless number would be the
Richardson number.
The mathematics of the flow is therefore simpler because the density ratio (
, a
dimensionless number) doesn't affect the flow; the Boussinesq approximation states that it may be assumed to be exactly one.
Inversions
One feature of Boussinesq flows is that they look the same when viewed upside-down, provided that the identities of the fluids are reversed. The Boussinesq approximation is
inaccurate when the nondimensionalised density difference
is of order unity.
For example, consider an open window in a warm room. The warm air inside is lighter than the cold air outside, which flows into the room and down towards the floor. Now imagine the opposite: a cold room exposed to warm outside air. Here the air flowing in moves up toward the ceiling. If the flow is Boussinesq (and the room is otherwise symmetrical), then viewing the cold room upside down is exactly the same as viewing the warm room right-way-round. This is because the only way density enters the problem is via the reduced gravity
which undergoes only a sign change when changing from the warm room flow to the cold room flow.
An example of a non-Boussinesq flow is bubbles rising in water. The behaviour of air bubbles rising in water is very different from the behaviour of water falling in air: in the former case rising bubbles tend to form hemispherical shells, while water falling in air splits into raindrops (at small length scales
surface tension enters the problem and confuses the issue).
Further Information
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