Tracer Particles and Seeding for PIV - PowerPoint PPT Presentation

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Tracer Particles and Seeding for PIV

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Title: PowerPoint Presentation Author: Xiangqun Song Last modified by: Hui Meng Created Date: 2/27/2001 6:42:52 PM Document presentation format: On-screen Show – PowerPoint PPT presentation

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Title: Tracer Particles and Seeding for PIV


1
Tracer Particles and Seeding for PIV
2
Seeding particles for PIV
  • Proper tracer must be small enough to follow
    (trace) fluid motion and should not alter fluid
    or flow properties.
  • Proper tracer must be large enough to be visible
    by the camera.
  • Uniform seeding is critical to the success of
    obtaining velocity field. No seed particles, no
    data.
  • The seeding source must be placed cleverly so
    that the particles mix with the flow well.
  • Particles with finite inertia are known to
    disperse non-uniformly in a turbulent flow,
    preferential concentration

3
Seeding particles for PIV (contd)
  • The tracing ability and the dispersion
    characteristics depends on the aerodynamical
    characteristics of particles and the continuous
    medium
  • The visibility depends on the scattering
    characteristics of particles.
  • The choice of optimal diameter for seeding
    particles is a compromise between two aspects.

4
Scattering characteristics of particles
  • Laser sheet leads to a low energy density
    particle scattering efficiency is important
  • Light scattering capability - scattering cross
    section Cs is defined as the ratio of the total
    scattered power Ps, to the laser intensity I0
    incident on the particle

5
Example of scattering cross section (1)
The scattering cross section as a function of the
particle size (refractive index m1.6).
6
Example of scattering cross section (2)
Scattering cross section as a function of the
particle size
7
Mie scattering of small particle (1)


Light Scattering by an oil particle in air when
refractive index m 1.4. Left 1mm diameter,
right 10mm diameter
8
Mie scattering of small particle (2)
Light scattering by a 1 mm, 10 mm, and 30 mm
glass particle in water. Refractive index m 1.52
9
Summary of particle light scattering for PIV
  • The ratio Is90/Is0 decreases with increasing size
    parameter dp/?, with values roughly in the range
    10-1-10-3 for scattering particles useful in PIV.
  • The resulting intensity of the scattered light
    for a given light sheet intensity will depend on
    the combined influences of Cs and Is90/Is0, which
    exhibit opposing tendencies with increasing
    particle size. In general, larger particles will
    still give stronger signals.
  • The ratio Is90/Is0 increases with increasing
    refractive index m. Hence particles in air gives
    stronger 90o scattering than in water.

10
Tracking characteristics of particles
  • The tracking ability depends on
  • Particle shape assumed spherical
    aerodynamically equivalent diameter - dp
  • Particle density ?p
  • Fluid density ?f and fluid dynamic viscosity ? or
    kinematic viscosity ? ?/?f
  • Newtons Law governing the motion of a single
    particle

11
General governing equation
  • Meaning of each term
  • Viscous drag according to the Stokes law
  • Acceleration force
  • Force due to a pressure gradient in the vicinity
    of the particle
  • Resistance of an inviscid fluid to the
    acceleration of the sphere (added mass)
  • Basset history integral resistance caused by
    the unsteadiness of the flow field.

12
Stokes drag law
  • The Stokes drag law is considered to apply when
    the particle Reynolds number Rep is smaller than
    unity, where Rep is defined as
  • In a typical PIV experiment with 10?m particles
    and 20 cm/s mean velocity,Rep10x10-6 x 0.2 /
    1.46x10-5 0.13 (air)Rep10x10-6 x
    0.2/1.0x10-6 2 (water).

13
Particle parameter - the particle response time
tp
  • Velocity lag of a particle in a continuously
    accelerating fluid
  • The particle velocity response to the fluid
    velocity if heavy particles (?pgtgt?f) in a
    continuously accelerating flow is
  • Particle response time

14
Particle parameter- the Stokes number St
  • Stokes number St as the ratio of the particle
    response time to the Kolmogorov time scale
  • St the degree of coupling between the particle
    phase and the fluid.
  • St?0 the particles behave like tracers
  • St?? the particles are completely unresponsive to
    the fluid flow.

15
Particle parameter- the characteristic frequency
C
  • In the case of gas flow where ?pgtgt?f,
    characteristic frequency of the particle motion
  • Tracing ability in turbulence, ?c2?fc

16
Figure of characteristic frequency
The response of particles in turbulence flow.
(From Haetig J, Introductory on particle behavior
ISL/AGRAD workshop on laser anemometry (Institute
Saint Louis) report R 117/76, 1976)
17
Particle size vs. Turbulence scale
  • Seeding particles need to be smaller than the
    smallest turbulence scale if one wants to
    identify all the structures in the vicinity of
    the flow. The smallest fluid length scale is
    called the Kolmogorov length scale, and it is
    related to the size of the smallest eddy.

18
Additional Considerations
  • Particle seeding uniformity

19
Additional Considerations (contd)
  • Secure sufficient spatial detail in the flow
    field a higher concentration of particles is
    generally needed with PIV than with LDV, with
    which it is possible to wait indefinitely for the
    arrival of a scattering particle in the probe
    volume.
  • A uniform particle size is desirable in order to
    avoid excessive intensity from larger particles
    and background noise, decreasing the accuracy,
    from small particles.
  • Particles that naturally exist in the flow seldom
    meet the above requirements. Hence, in PIV
    applications, it is often necessary to seed the
    flow with a chosen tracer particle. The
    particles are either premixed with the whole
    fluid (e.g., stirred ) or released in situ by a
    seeding source.

20
Imaging of small particles
  • Relation between real particles and particle
    image recorded in the camera can be analyzed by
    the diffraction limited imaging of a small
    particle
  • For a given aperture
  • diameter Da and wavelength ?, the Airy spot size

21
Imaging of small particles (conts)
  • With an imaging lens, the diffraction-limited
    size
  • Estimate of the particle image diameter

dp original particle diameter
22
Seeding particles for PIV (liquid flow)
23
Seeding particles for PIV (gas)
24
Commercial seeding particles - TSI
(http//www.tsi.com)
  • Silicon Carbide Suitable for measurements in
    liquids and gases, silicon carbide particles have
    a narrow particle size distribution (mean
    diameter of 1.5?m). Their high refractive index
    is useful for obtaining good signals in water,
    even in backscatter operation. They can also be
    used in high temperature flows. Supplied as a dry
    powder, they can be mixed in liquid to form a
    suspension before dispersing.
  • Titanium Dioxide Titanium dioxide particles
    (mean diameter of 0.2?m) are usually dispersed as
    a dry powder for gas flow measurement
    applications. The smaller particle size makes
    titanium dioxide attractive for high-speed flows.
    It can also be used for high temperature flows.

25
Commercial seeding particles - TSI
(http//www.tsi.com) (contd)
  • Polystyrene Latex With an extremely narrow size
    distribution (nominal diameter of 1.0?m),
    polystyrene latex (PSL) particles are useful in
    many different measurements. Supplied in water,
    they are not recommended for high temperature
    applications.
  • Metallic coated Metallic coated particles (mean
    diameter of 9.0?m) are normally used to seed
    water flows for LDV measurements due to their
    lower density and higher reflectivity. They
    cannot be used where salt is present. Salt reacts
    with the metal coating, causing the particles to
    agglomerate and drop out of the flow.

26
Commercial seeding particles - TSI
(http//www.tsi.com) (contd)
27
Commercial seeding particles - Dantec
(http//www.dantecmt.com)
  • Polyamide seeding particles (PSP) These are
    produced by polymerisation processes and
    therefore have a round but not exactly spherical
    shape. They are microporous and strongly
    recommended for water flow applications.
  • Hollow glass spheres and silver-coated hollow
    glass spheres (HGS, S-HGS) Intended primarily
    for liquid flow applications, these are
    borosilicate glass particles with a spherical
    shape and a smooth surface. A thin silver coating
    further increases reflectivity.
  • Fluorescent polymer particles (FPP) These
    particles are based on melamine resin.
    Fluorescent dye (Rhodamine B) is homogeneously
    distributed over the entire particle volume. In
    applications with a high background light level,
    fluorescent seeding particles can significantly
    improve the quality of vector maps from PIV and
    LDV measurements. The receiving optics must be
    equipped with a filter cantered on the emission
    wavelength (excitation max. 550 nm emission
    max. 590 nm).

28
Commercial seeding particles - Dantec
(http//www.dantecmt.com) (contd)
29
Particle generation
  • Liquid flow
  • Simple, select proper powder then mix w/ liquid
  • Gas flow
  • liquid droplets
  • Atomization or Condensation
  • solid particles
  • Atomization or Fluidization
  • Requirement for PIV
  • Nearly monodisperse size distribution
  • High production rate

30
Liquid droplets
  • Advantage
  • Steady production rate
  • Inherently spherical shape
  • Known refractive index
  • Problem
  • Form non-uniform liquid films on window
  • Generator
  • Laskin atomizer
  • Commercial atomizer (e.g., TSI)
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