In
dimensional analysis
In engineering and science, dimensional analysis is the analysis of the relationships between different physical quantities by identifying their base quantities (such as length, mass, time, and electric current) and units of measure (such as mi ...
, the Strouhal number (St, or sometimes Sr to avoid the conflict with the
Stanton number) is a
dimensionless number
A dimensionless quantity (also known as a bare quantity, pure quantity, or scalar quantity as well as quantity of dimension one) is a quantity to which no physical dimension is assigned, with a corresponding SI unit of measurement of one (or 1) ...
describing oscillating flow mechanisms. The parameter is named after
Vincenc Strouhal
Vincenc Strouhal (Čeněk Strouhal) (10 April 1850 in Seč – 26 January 1922 in Prague) was a Czech physicist specializing in experimental physics. He was one of the founders of the Institute of Physics of the Czech part of Charles Universit ...
, a Czech physicist who experimented in 1878 with wires experiencing
vortex shedding
In fluid dynamics, vortex shedding is an oscillating flow that takes place when a fluid such as air or water flows past a bluff (as opposed to streamlined) body at certain velocities, depending on the size and shape of the body. In this flow, v ...
and singing in the wind. The Strouhal number is an integral part of the fundamentals of
fluid mechanics
Fluid mechanics is the branch of physics concerned with the mechanics of fluids ( liquids, gases, and plasmas) and the forces on them.
It has applications in a wide range of disciplines, including mechanical, aerospace, civil, chemical and ...
.
The Strouhal number is often given as
where ''f'' is the frequency of
vortex shedding
In fluid dynamics, vortex shedding is an oscillating flow that takes place when a fluid such as air or water flows past a bluff (as opposed to streamlined) body at certain velocities, depending on the size and shape of the body. In this flow, v ...
, ''L'' is the characteristic length (for example,
hydraulic diameter The hydraulic diameter, , is a commonly used term when handling flow in non-circular tubes and channels. Using this term, one can calculate many things in the same way as for a round tube. When the cross-section is uniform along the tube or channel ...
or the
airfoil thickness) and ''U'' is the
flow velocity
In continuum mechanics the flow velocity in fluid dynamics, also macroscopic velocity in statistical mechanics, or drift velocity in electromagnetism, is a vector field used to mathematically describe the motion of a continuum. The length of the f ...
. In certain cases, like heaving (plunging) flight, this characteristic length is the amplitude of oscillation. This selection of characteristic length can be used to present a distinction between Strouhal number and reduced frequency:
where ''k'' is the
reduced frequency Reduced frequency is the dimensionless number used in general for the case of unsteady aerodynamics and aeroelasticity. It is one of the parameters that defines the degree of unsteadiness of the problem.
For the case of Aeroelasticity#Flutter, flut ...
, and ''A'' is amplitude of the heaving oscillation.
For large Strouhal numbers (order of 1), viscosity dominates fluid flow, resulting in a collective oscillating movement of the fluid "plug". For low Strouhal numbers (order of 10
−4 and below), the high-speed, quasi-steady-state portion of the movement dominates the oscillation. Oscillation at intermediate Strouhal numbers is characterized by the buildup and rapidly subsequent shedding of vortices.
For spheres in uniform flow in the
Reynolds number range of 8×10
2 < Re < 2×10
5 there co-exist two values of the Strouhal number. The lower frequency is attributed to the large-scale instability of the wake, is independent of the
Reynolds number Re and is approximately equal to 0.2. The higher-frequency Strouhal number is caused by small-scale instabilities from the separation of the shear layer.
Derivation
Knowing
Newton’s Second Law stating force is equivalent to mass times acceleration, or
, and that acceleration is the derivative of velocity, or
(characteristic speed/time) in the case of fluid mechanics, we see
,
Since characteristic speed can be represented as length per unit time,
, we get
,
where,
: ''m'' = mass,
: ''U'' = characteristic speed,
: ''L'' = characteristic length.
Dividing both sides by
, we get
⇒
,
where,
: ''m'' = mass,
: ''U'' = characteristic speed,
: ''F'' = net external forces,
: ''L'' = characteristic length.
This provides a dimensionless basis for a relationship between mass, characteristic speed, net external forces, and length (size) which can be used to analyze the effects of fluid mechanics on a body with mass.
If the net external forces are predominantly elastic, we can use
Hooke’s Law
In physics, Hooke's law is an empirical law which states that the force () needed to extend or compress a spring by some distance () scales linearly with respect to that distance—that is, where is a constant factor characteristic of th ...
to see
,
where,
: ''k'' = spring constant (stiffness of elastic element),
: ''ΔL'' = deformation (change in length).
Assuming
, then
. With the natural resonant frequency of the elastic system,
, being equal to
, we get
,
where,
: ''m'' = mass,
: ''U'' = characteristic speed,
: ''
'' = natural resonant frequency,
: ''ΔL'' = deformation (change in length).
Given that cyclic motion frequency can be represented by
we get,
,
where,
: ''f'' = frequency,
: ''L'' = characteristic length,
: ''U'' = characteristic speed.
Applications
Micro/Nanorobotics
In the field of micro and nanorobotics, the Strouhal number is used alongside the
Reynolds number in analyzing the impact of an external oscillatory fluidic flow on the body of a microrobot. When considering a microrobot with cyclic motion, the Strouhal number can be evaluated as
,
where,
: ''f'' = cyclic motion frequency,
: ''L'' = characteristic length of robot,
: ''U'' = characteristic speed.
The analysis of a microrobot using the Strouhal number allows one to assess the impact that the motion of the fluid it is in has on its motion in relation to the inertial forces acting on the robot–regardless of the dominant forces being elastic or not.
Medical
In the medical field, microrobots that use swimming motions to move may make micromanipulations in unreachable environments.
The equation used for a blood vessel:
,
where,
: ''f'' = oscillation frequency of the microbot swimming motion
: ''D'' = blood vessel diameter
: ''V'' = unsteady viscoelastic flow
The Strouhal number is used as a ratio of the
Deborah number The Deborah number (De) is a dimensionless number, often used in rheology to characterize the fluidity of materials under specific flow conditions. It quantifies the observation that given enough time even a solid-like material might flow, or a flui ...
(De) and
Weissenberg number
The Weissenberg number (Wi) is a dimensionless number used in the study of viscoelastic flows. It is named after Karl Weissenberg. The dimensionless number compares the elastic forces to the viscous forces. It can be variously defined, but it is u ...
(Wi):
.
The Strouhal number may also be used to obtain the
Womersley number
The Womersley number (\alpha or \text) is a dimensionless number in biofluid mechanics and biofluid dynamics. It is a dimensionless expression of the pulsatile flow frequency in relation to viscous effects. It is named after John R. Womersley ...
(Wo). The case for blood flow can be categorized as an unsteady viscoelastic flow, therefore the Womersley number is
,
Or considering both equations,
.
Metrology
In
metrology, specifically
axial-flow turbine meters, the Strouhal number is used in combination with the
Roshko number In fluid mechanics, the Roshko number (Ro) is a dimensionless number describing oscillating flow mechanisms. It is named after the American Professor of Aeronautics Anatol Roshko. It is defined as
: \mathrm = =\mathrm\,\mathrm
: \mathrm= ,
: \ ...
to give a correlation between flow rate and frequency. The advantage of this method over the frequency/viscosity versus K-factor method is that it takes into account temperature effects on the meter.
where,
: ''f'' = meter frequency,
: ''U'' = flow rate,
: ''C'' = linear coefficient of expansion for the meter housing material.
This relationship leaves Strouhal dimensionless, although a dimensionless approximation is often used for ''C''
3, resulting in units of pulses/volume (same as K-factor).
This relationship between flow and frequency can also be found in the aeronautical field. Considering pulsating methane-air coflow jet diffusion flames, we get
,
where,
: ''a'' = fuel jet radius
: ''w'' = the modulation frequency
: ''U'' = exit velocity of the fuel jet
For a small Strouhal number (St=0.1) the modulation forms a deviation in the flow that travels very far downstream. As the Strouhal number grows, the non-dimensional frequency approaches the natural frequency of a flickering flame, and eventually will have greater pulsation than the flame.
Animal locomotion
In swimming or flying animals, Strouhal number is defined as
where,
: ''f'' = oscillation frequency (tail-beat, wing-flapping, etc.),
: ''U'' = flow rate,
: ''A'' = peak-to-peak oscillation amplitude.
In animal flight or swimming, propulsive efficiency is high over a narrow range of Strouhal constants, generally peaking in the 0.2 < St < 0.4 range.
This range is used in the swimming of dolphins, sharks, and bony fish, and in the cruising flight of birds, bats and insects.
However, in other forms of flight other values are found.
Intuitively the ratio measures the steepness of the strokes, viewed from the side (e.g., assuming movement through a stationary fluid) – ''f'' is the stroke frequency, ''A'' is the amplitude, so the numerator ''fA'' is half the vertical speed of the wing tip, while the denominator ''V'' is the horizontal speed. Thus the graph of the wing tip forms an approximate sinusoid with aspect (maximal slope) twice the Strouhal constant.
Efficient motion
The Strouhal number is most commonly used for assessing oscillating flow as a result of an object's motion through a fluid. The Strouhal number reflects the difficulty for animals to travel efficiently through a fluid with their cyclic propelling motions. The number relates to propulsive efficiency, which peaks between 70-80% when within the optimal Strouhal number range of 0.2 to 0.4. Through the use of factors such as the stroke frequency, the amplitude of each stroke, and velocity, the Strouhal number is able to analyze the efficiency and impact of an animal's propulsive forces through a fluid, such as those from swimming or flying. For instance, the value represents the constraints to achieve greater propulsive efficiency, which affects motion when cruising and aerodynamic forces when hovering.
Greater reactive forces and properties that act against the object, such as viscosity and density, reduce the ability of an animal's motion to fall within the ideal Strouhal number range when swimming. Through the assessment of different species that fly or swim, it was found that the motion of many species of birds and fish falls within the optimal Strouhal range.
However, the Strouhal number varies more within the same species than other species based on the method of how they move in a constrained manner in response to aerodynamic forces.
=Example: Alcid
=
The Strouhal number has significant importance in analyzing the flight of animals since it is based on the streamlines and the animal's velocity as it travels through the fluid. Its significance is demonstrated through the motion of
alcids
An auk or alcid is a bird of the family Alcidae in the order Charadriiformes. The alcid family includes the murres, guillemots, auklets, puffins, and murrelets. The word "auk" is derived from Icelandic ''álka'', from Old Norse ''alka'' (a ...
as it passes through different mediums (air to water). The assessment of alcids determined the peculiarity of being able to fly under the efficient Strouhal number range in air and water despite a high mass relative to their wing area.
The alcid’s efficient dual-medium motion developed through natural selection where the environment played a role in the evolution of animals over time to fall under a certain efficient range. The dual-medium motion demonstrates how alcids had two different flight patterns based on the stroke velocities as it moved through each fluid.
However, as the bird travels through a different medium, it has to face the influence of the fluid’s density and viscosity. Furthermore, the alcid also has to resist the upward-acting buoyancy as it moves horizontally.
Scaling of the Strouhal number
Scale Analysis
In order to determine significance of the Strouhal number at varying scales, one may perform
scale analysis–a simplification method to analyze the impact of factors as they change with respect to some scale. When considered in the context of microrobotics and nanorobotics, size is the factor of interest when performing scale analysis.
Scale analysis of the Strouhal number allows for analysis of the relationship between mass and inertial forces as both change with respect to size. Taking its original underived form,
, we can then relate each term to size and see how the ratio changes as size changes.
Given
where m is mass, V is volume, and
is density, we can see mass is directly related to size as volume scales with length (L). Taking the volume to be
, we can directly relate mass and size as
.
Characteristic speed (U) is in terms of
, and relative distance scales with size, therefore
.
The net external forces (F) scales in relation to mass and acceleration, given by
. Acceleration is in terms of
, therefore
. The mass-size relationship was established to be
, so considering all three relationships, we get
.
Length (L) already denotes size and remains L.
Taking all of this together, we get
.
With the Strouhal number relating the mass to inertial forces, this can be expected as these two factors will scale proportionately with size and neither will increase nor decrease in significance with respect to their contribution to the body’s behavior in the cyclic motion of the fluid.
Relationship with the Richardson number
The scaling relationship between the
Richardson number The Richardson number (Ri) is named after Lewis Fry Richardson (1881–1953). It is the dimensionless number that expresses the ratio of the buoyancy term to the flow shear term:
:
\mathrm = \frac = \frac \frac
where g is gravity, \rho is de ...
and the Strouhal number is represented by the equation:
,
where a and b are constants depending on the condition.
For round helium buoyant jets and plumes:
.
When
,
.
When
,
.
For planar buoyant jets and plumes:
.
For shape-independent scaling:
Relationship with Reynolds number
The Strouhal number and
Reynolds number must be considered when addressing the ideal method to develop a body made to move through a fluid. Furthermore, the relationship for these values is expressed through Lighthill's elongated-body theory, which relates the reactive forces experienced by a body moving through a fluid with its inertial forces.
The Strouhal number was determined to depend upon the dimensionless Lighthill number, which in turn relates to the Reynolds number. The value of the Strouhal number can then be seen to decrease with an increasing Reynolds number, and to increase with an increasing Lighthill number.
See also
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References
External links
Vincenc Strouhal, Ueber eine besondere Art der Tonerregung
{{Authority control
Dimensionless numbers of fluid mechanics
Fluid dynamics