Download Hot Wire Anemometry and Fluid Flow Measurement

By Mehak Chopra
Indian Institute of Technology Delhi
Guide: Dr B. Uensal
Outline
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Characteristics of an ideal instrument
Hot Wire Anemometry
Advantages and Drawbacks of Hot Wire Anemometry
Principle of Operation
Basic Construction of Hot Wire Probe
Modes of Operation of Hot Wire Anemometers
Governing Equation and Model of HWA
Calibration
Directional Sensitivity
Turbulence Measurement using HWA
Hot Wire Anemometry and Fluid Flow Measurement
Fluid Flow
 Fluid flow is ubiquitous ! e.g processes in our body, Flow around airplanes etc ‐ it is essential to measure fluid flow.
 Most practical flows are turbulent. Hence it is equally important to measure Turbulent Fluctuations.
 Pitot tube – low frequency response
 Many Methods to measure velocity – discussed earlier
Hot Wire Anemometry and Fluid Flow Measurement
Characteristics of an ideal Instrument to measure Velocity Fluctuations
 Good Signal Sensitivity: Measurable change in output for small changes in velocity
 High Frequency Response: to accurately follow transients without any time lag
 Wide velocity range
 Create minimal flow disturbance
 Good Spatial Resolution  Low in cost
 High Accuracy
 Measure velocity component and Detect flow reversal
 Easy to use
Hot Wire Anemometry and Fluid Flow Measurement
In making measurements, it is not a question of the best instrument but rather which instrument will perform best for the specific application.
Hot Wire Anemometry and Fluid Flow Measurement
Hot Wire Anemometry
 Intrusive Technique
 Measurement of instantaneous velocities and temperature at a point in a flow.
 Hot wire anemometry is an ideal tool for measurement of velocity fluctuations in time domain in turbulent flows
 Principal tool for basic studies of physics of turbulent flows.
 Development of realistic turbulence models, HWA necessary to carry out fundamental turbulence studies
Hot Wire Anemometry and Fluid Flow Measurement
Advantages of HWA
 Good Frequency response: Measurements to several hundred kHz possible, 1 MHz also feasible
 Velocity Measurement: measures magnitude and direction of velocity and velocity fluctuations, Wide velocity range
 Temperature Measurements  Two Phase Flow: Measurements in flows containing continuous turbulent phase and distributed bubbles.
Hot Wire Anemometry and Fluid Flow Measurement
Advantages of HWA
 Signal to noise ratio : have low noise levels. Resolution of 1 part in 10000 is accomplished
 Signal Analysis: Output is continuous analogue signal, both time domain and frequency domain analysis can be carried out. Output can also be processed by digital systems.
 Measurement of turbulent quantities like vorticity, dissipation rate etc.
Hot Wire Anemometry and Fluid Flow Measurement
Drawbacks
 Intrusive Technique: modification of local flow field
 High Turbulence‐Intensity Flows:
 Errors due to neglecting higher order terms
 Rectification Error – insensitive to reversal of flow direction.
 Contamination: Deposition of impurities in flow on sensor alter the calibration characteristics and reduce frequency response.
 Probe breakage and burn out
 Unable to fully map velocity fields that depend strongly on space coordinates and simultaneously on time.
 Spatial array of many probes would be required.
 Fails in hostile environment like combustion
Hot Wire Anemometry and Fluid Flow Measurement
Principle of Operation
 Based on convective heat transfer from a heated sensing element, possessing temperature coefficient of resistance.
Flow Rate varies
Convective heat transfer coefficient (h) varies
Heat transfer from filament varies
Operation of Hot Wire Sensor
Hot Wire Anemometry and Fluid Flow Measurement
Hot Wire Probe
Structure of hot wire probe
Hot Wire Anemometry and Fluid Flow Measurement
Characteristics of material used for making sensor
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High Temperature Coefficient of resistance
High Specific Resistance
High Mechanical Strength
Good Oxidation Resistance
Low Thermal Conductivity
Availability in small diameters
Tungsten : good strength, poor oxidation resistance
Platinum: good oxidation resistance, weak
Tungsten with thin platinum coating is generally used.
At high temperatures – Platinum‐iridium alloys, Platinum‐
rhodium alloys are used.
Hot Wire Anemometry and Fluid Flow Measurement
Wire Dimensions
 Large aspect ratios – i.e l/d where l is the wire length and d is the wire diameter, to minimize conduction losses to supports and have uniform temperature distribution
 Small diameter are preferred even though they have less strength as:
 maximizes time response due to low thermal inertia
 maximize spatial resolution
 improves signal to noise ratio at high frequencies
 eliminates output noise
Hot Wire Anemometry and Fluid Flow Measurement
Classification of Hot Wire Probes
On the basis of number of sensors:
Single Sensor Probe Dual Sensor Probe Triple Sensor Probe
( X probes,
Split Fibre probes)
Information about magnitude and direction of velocity can
be obtained with probes having 2 or more sensors
Hot Wire Anemometry and Fluid Flow Measurement
Modes of Operation of Hot Wire Anemometers Constant Current Constant Temperature
 Current in the wire is kept constant
 Temperature hence Resistance
of the wire is kept constant by using a servo amplifier
 Variations in wire resistance
caused by the flow are measured by monitoring the voltage drop variations across the filament.
 The measurable signal when a change in flow velocity occurs is the change in current to be fed to the sensor.
Hot Wire Anemometry and Fluid Flow Measurement
Basic Circuitry of Constant Current Anemometer
Circuit Diagram of Constant Current Anemometer
Hot Wire Anemometry and Fluid Flow Measurement
Basic Circuitry of Constant Temperature Anemometer
Velocity Varies
Error Voltage (e2 – e1) varies
Input Voltage to amplifier varies
Change in current i through the sensor
Restores the resistance of sensor to original value
CCA vs CTA
 Compensation of Thermal inertia of the filament is automatically adjusted in CTA as the flow conditions vary.
 CTA is used the same way as it is calibrated. Calibration is dynamic in this case, while in CCA instrument is calibrated at constant temperature and used in a constant current mode.
 In constant current mode, wire can be destroyed by burning out if velocity is very small. There is no such danger in CTA
 In CTA there is no thermal cycling hence long life of probe. Hot Wire Anemometry and Fluid Flow Measurement
CTA Measuring Chain
Basic CTA Measuring Chain
Hot Wire Anemometry and Fluid Flow Measurement
General Hot Wire Equation
Where:
W – power generated by joule heating given by I2Rw where Rw = Rw (Tw)
Q – heat transfer rate to surrounding Qi – thermal energy stored in the wire (CwTw) Cw – Heat capacity of wire
Tw– Temperature of wire
Hot Wire Anemometry and Fluid Flow Measurement
Q = Qfc + Qnc + Qr + Qc
Forced convection term given by h*A*(Tw –
TA )
Radiation to natural surrounding convection given by
term
where
A is the area of the wire
TA is the temperature of the fluid
h is the heat transfer coefficient
σ is the Stefan ‐Boltzmann constant ε is the emissivity
k is the thermal conductivity
A*σ*ε*(T4w –
T4A)
Conduction
to prongs given by ‐
(k*A*dT/dx)
Hot Wire Anemometry and Fluid Flow Measurement
Heat Transfer due to radiation
Performing an energy balance on this differential element, neglecting radiation and self convection we get:
Hot Wire Anemometry and Fluid Flow Measurement
 Natural Convection:  is effective at very low velocities.
 It depends on the value of Grashof number Gr (
)  According to Collis and Williams (1959), It can be neglected for hot wire probes with large values of aspect ratio, if Re>Gr1/3
 Radiation: in most hot wire anemometer applications this term is very small and can be neglected
Hot Wire Anemometry and Fluid Flow Measurement
 Conduction:
 Conductive heat transfer takes place towards the prongs resulting in temperature distribution in wire.
Temperature Profile in Hot Wire
 To minimize conductive end losses, wire should be as long as possible and possess low value of thermal conductivity
 For wires with large aspect ratios (l/d) heat losses by conduction can be neglected.
Hot Wire Anemometry and Fluid Flow Measurement
Forced Convection: plays the main role in heat transferred to the surrounding.
 It depends upon Nusselt number
Where Re = Reynolds number
Pr = Prandtl number which accounts for fluid properties. (generally constant)
α1= angle between free stream flow direction and flow normal to the cylinder
Gr = Grashof number which accounts for free convection (buoyancy) effects
Ma = Mach number which accounts for compressibility effects
γ = Cp/ Cv
at = overheat ratio or temperature loading (Tw – Ta)/ Ta
2l/d = accounts for sensors dimension
kf/kw = ratio of thermal conductivity of fluid to sensor
Hot Wire Anemometry and Fluid Flow Measurement
Assumption:
 Flow is incompressible
 Wire is normal to the flow (α1 = 0)
 No effect of free convection and conduction(basically assuming infinitely long wire)
Nu = Nu(Re) According to King, for an infinitely long wire
Nu = X + YRe1/2 (Kings Law)
Kramers proposed that for 0.01<Re<10000 and
0.71<Pr<1000 and evaluating the fluid properties at
Tf = (Tw + Ta)/2, Nu can be given by:
Hot Wire Anemometry and Fluid Flow Measurement
Simple Model for Hot Wire Anemometer
 Considering only forced convection as the mode of heat exchange and not considering heat storage term:
Where Tw= Temperature of wire
Ta = Temperature of fluid
 As , hence
 Resistance is a function of temperature:
Hot Wire Anemometry and Fluid Flow Measurement
Simple Model for Hot Wire Anemometer
 Thus putting the value of Nu (by Kings Law) and expressing resistance as a function of temperature,  Hence for finite length hot wire anemometer,
)
 In terms of voltage Ew,
 For CTA, as temperature and resistance are constant, Hot Wire Anemometry and Fluid Flow Measurement
Dynamic Characteristics  Wire not respond instantaneously due to its thermal inertia.  Dampen the variation in wire resistance Rw and result in flow fluctuation measured smaller than they are.
 Heat Storage term needs to be accounted in heat balance equation
Cw = thermal capacity Hot Wire Anemometry and Fluid Flow Measurement
Dynamic Characteristics
 The above differential equation has time constant τ given by
 Frequency limit is given by Exponential change in resistance of wire with instantaneous rise in velocity Hot Wire Anemometry and Fluid Flow Measurement
Frequency Response of CTA
 The servo‐loop amplifier reduces the time constant and increases the wire frequency limit.
where τw = wire time constant alone and = a = overheat ratio
Rw = wire resistance
S = amplifier gain
Amplitude transfer function for velocity fluctuation
Hot Wire Anemometry and Fluid Flow Measurement
Methods to Determine Dynamic Response of CTA
 A small electronic square wave signal is injected into the bridge and response of anemometer voltage E is observed.  Output voltage response to this current signal has the same time constant as the response to the flow velocity signal
Square wave test response of CTA
Hot Wire Anemometry and Fluid Flow Measurement
Calibration
 Probe is exposed to a set of known velocities and output voltage E is recorded.  Should be done at low turbulence intensities and constant temperature
 Pitot‐static tube is generally used for velocity measurement.
Calibration of hot wire sensor using pitot tube
Where h is total pressure in height of flowing fluid.
Hot Wire Anemometry and Fluid Flow Measurement
Calibration
 Calibration curve is plotted between Hot Wire Voltage and Velocity.
 Typical Calibration curve is nonlinear and sensitivity decreases as velocity increases.
 As constants A, B and n can be determined by regression analysis Hot Wire Anemometry and Fluid Flow Measurement
Directional Sensitivity of Hot wire probes
 For an infinitely long sensor, heat transfer varies with the cosine of angle between the velocity and the wire normal and Velocity along the sensor has no cooling effect.
 For a finite length sensor, a directional sensitivity factor k (yaw factor) is introduced, which describes prong interference.
 For 3‐dimensional flows, pitch factor h is introduce
 Effective cooling velocity is given by:
Hot Wire Anemometry and Fluid Flow Measurement
Directional Sensitivity of Hot wire probes
E2 = A + B(Ueff)n
Hot Wire Anemometry and Fluid Flow Measurement
Determination of Direction
 To determine direction using a single wire probe, Rotate the probe in the flow.
 The orientation which gives maximum current is the direction of flow
Hot Wire Anemometry and Fluid Flow Measurement
Turbulence Measurements
 Instantaneous velocity in turbulent flow can be expressed as:
u(t) = ū + u’(t)
where ū is the mean velocity and u’ is the fluctuating component.
 Mean velocity is given by :
 Time average of fluctuating component is zero
Hot Wire Anemometry and Fluid Flow Measurement
Turbulence Measurements
 However, the second moment of turbulent fluctuations or variance <(u’)2> is not zero and is a measure of intensity of fluctuations
 Standard deviation of velocity (σ) or urms is square root of variance.
 Turbulence Intensity =
Hot Wire Anemometry and Fluid Flow Measurement
Turbulence Measurements
 Velocity Sensitivity is given ( )
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 Thus fluctuating component of velocity is related to fluctuating voltage e’:
e’ = u’
 Hence if calibration constants are known, fluctuation in velocity can be calculated by fluctuation in voltage
Hot Wire Anemometry and Fluid Flow Measurement
Filtering and Signal Dynamic Range
 Voltage fluctuations may be very small compared to mean voltage.
 Difficult for ADC to measure both average and fluctuating components.
 Anemometer output is sent to a high pass filter which eliminates mean value <E> of voltage
 Output of high pass filter is sent to an oscilloscope inorder to observe peak‐peak fluctuations and set the amplifier gain. Hot Wire Anemometry and Fluid Flow Measurement
Grid Generated Turbulence
Mesh size (M) = one side of the open square of grid.
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Many methods to generate turbulence for experimentation.
Square mesh grid is placed in the cross section to generate turbulence
Grid generated turbulence is homogenous and isotropic
Used with HWA to provide data for development of turbulence models e.g. to evaluate theory for the decay of turbulence.
Hot Wire Anemometry and Fluid Flow Measurement
High contraction ratio anomaly of axisymmetric contraction
of grid‐generated turbulence [1]
 Experiments reported anomalous increase in second order moments of longitudinal velocity fluctuations in measuring properties of axisymmetric strained turbulence
 This anomaly was resolved by removing the experimental inaccuracies and gave results in agreement with direct numerical simulations and turbulence theory
 Studies were carried in a wind tunnel in which there was grid generated turbulence and hot wire probes were used Hot Wire Anemometry and Fluid Flow Measurement
References
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Özgür Ertunç and Franz Durst, “On the high contraction ratio anomaly of axisymmetric contraction of grid‐generated turbulence”, PHYSICS OF FLUIDS 20, 025103 2008
Bruun H.H, “Hot Wire Anemometry‐Principal and Signal Analysis”, Oxford University Press
Perry A.E, “Hot‐Wire Anemometry”, Oxford Science Publication
Smol’yakov A.V. and Tkachenko V.M. ,“ The Measurement of Turbulent Fluctuations”, Springer‐Verlag Berlin Heidelberg 1983
Goldstein R.J,“Fluid Mechanics Measurement”, Hemisphere Publishing
Jorgensen F.E(2002), “ How to measure turbulence with hot wire anemometers – a practical guide”
Tropea C et al, “Springer Handbook of Experimental Fluid Mechanics” Springer
Hot Wire Anemometry and Fluid Flow Measurement
Hot Wire Anemometry and Fluid Flow Measurement
Compressibility Effects
 For high velocity flows, compressibility effects become significant.
 Need to consider Mach number Ma and Cp
 Knudsen number (Kn) is important parameter for low density flows and is given by:
where λ = molecular mean free path
 In this case Nu = Nu(Re, Kn)
Hot Wire Anemometry and Fluid Flow Measurement
Hot Film Probes
 Platinum or nickel film are deposited on thermally insulating substrate like quartz.
 Used in liquid flows and high temperature ultrasonic gas flows due to their sturdy construction
Hot Wire Anemometry and Fluid Flow Measurement
Turbulent Flows
 Most practical flows are turbulent.
 Contribute significantly to transport of momentum, heat and mass.
 A complex, unpredictable and random process.
 Responsible for most fluid friction losses.
 Rational design of airplanes, ships, turbines etc – have to consider turbulence.
Hence it is equally important to measure Turbulent Fluctuations
Hot Wire Anemometry and Fluid Flow Measurement
Measurement of Integral Properties
Diagram of Pitot Tube
 Instruments like Pitot tubes, venturimeters ‐ Only measure integral properties like mean velocity.
 Differential pressure meters
 Low frequency response
 Do not respond to fluctuations in velocity, hence unable to measure turbulence.
Hot Wire Anemometry and Fluid Flow Measurement
Methods To Measure Turbulence Fluctuations
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Hot Wire Anemometry
Laser Doppler Anemometry
Particle Imaging Velocimetry
Flow Visualization
Acoustic Anemometry
Thermal Markers
Discharge Anemometry
Hot Wire Anemometry and Fluid Flow Measurement
Computational Fluid Dynamics
 Turbulence modeling is an important issue in CFD
 Measurements are made as a supplement to computer modeling
 These methods provide high quality experimental flow data for validation of existing computer codes containing turbulence models
Hot Wire Anemometry and Fluid Flow Measurement