chapter 8_lecture 3
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lcutre8TRANSCRIPT
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Fluid Mechanics
Chapter 8
Internal Incompressible
Viscous Flow
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Main Topics
Flow Measurement
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Flow Measurement
Now we know what Q or V is
But how do we measure them?
Flow meters
Choice of a flow meter? Accuracy
Range
Cost
Ease of reading
Service life
The simplest and cheapest that give the desired
accuracy and range
-
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Direct Methods (amount, not rate)• Collect an amount of fluid in a container over a fixed time
period
• It volume of fluid and time interval are known, Q, V can be calculated
• Compressible flows (or gas flows) are more difficult
• Advantage? No calibration required
• E.g.
Munson et al.
Flow Measurement
Water meter; or nutating disk flowmeter
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Flow Measurement
Direct Methodso Bellow type flow meter or gas meter
Contain bellows that fill and empty alternatively due to pressure of gas and motion of valves
E.g., household gas meters
Munson et al.
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Restriction Flow Meters for Internal Flows• Examples: Orifice Plate; Flow Nozzle; Venturi; Laminar Flow
Element
Flow Measurement
Venturi
Orifice Plate
Flow Nozzle
o Based on acceleration of fluid through an opening.
o Change in velocity results in change in pressure
o ΔP is measured and flowrate inferred theoretically
or empirically
From Bernoulli and continuity
Theoretical and actual flowrates can be obtained
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Flow Measurement
Traversing Methods• Examples: Pitot (or Pitot Static) Tube
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Static
(thermodynamic)
pressure
Stagnation
(total)
pressure
Pitot (total head)
tube
Flow Measurement
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Flow Measurement
Linear Flow Meters• Examples: Float Meter (Rotameter)
Munson et al.
o A float in a tapered tube
o It rises to an equilibrium height
which is a function of flowrate
o At that height, the net force on
float is zero, i.e., buoyancy, float
weight, fluid drag
o Calibration scale on tube gives
flowrate
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Flow Measurement
Linear Flow Meters• Examples: Turbine-type
Munson et al.
o The turbine rotates with an
angular velocity
o This is a function of the average
fluid velocity in the pipe.
o Magnetic sensor picks up the
velocity
o It’s calibrated for flow rate.
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Other Linear Flow Meters• Vortex; Electromagnetic; Magnetic; Ultrasonic
Flow Measurement
Others• Particle image velocimeters, hot-wire and Laser Doppler
Anemometer
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HWA or HFA Constant temperature (preferred)
Constant current
Velocity Measurements
http://www.dantecdynamics.com/Default.aspx?ID=1057
A & B = constants
King’s relation
Calibration required
o The working principle is based on the cooling effect of a flow on a heated body.
Convective heat transfer Q from a wire
placed normal to the flow is a function of
the velocity U.
Directional ambiguity
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LDA – uses Doppler effect Moving particle scatters light at different freq. origin
Velocity Measurements
http://www.dantecdynamics.com/Default.aspx?ID=1046
fD = n/λU(l1-l2)U = particle velocityλ = wavelength of light
sourcen = refractive index of
medium
No calibration required
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Target area is subdivided into smaller areas –interrogation areas
Correlation is applied to obtain particle displacement
A velocity vector is determined for each interrogation area
PIV Principles
http://www.dantecdynamics.com/Default.aspx?ID=820
Velocity Measurements
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http://media.gm.com/content/media/us/en/news/
news_detail.brand_gm.html/content/Pages/news/us/
en/2010/Aug/0804_windtunnel
http://www.seriouswheels.com/2005/2005-Pagani-Zonda-F-
Wind-Tunnel-1600x1200.htm
Flow visualization
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References
Fundamentals of Fluid Mechanics, B.R. Munson, T.H.
Okiishi, W.W. Huebsch, A.P. Rothmayer, 7th ed., Wiley, New
York (2013).
news_detail.brand_gm.html/content/Pages/news/us/en/2010
/Aug/0804_windtunnel
http://www.seriouswheels.com/2005/2005-Pagani-Zonda-F-
http://www.dantecdynamics.com/Default.aspx?ID=820
http://www.dantecdynamics.com/Default.aspx?ID=1046
http://www.dantecdynamics.com/Default.aspx?ID=1057