Air Speed Calibration Facility by using LDV and
Air. Speed Calibration Facility by using LDV and A Wind Tunnel at CMS Cheng-Tsair Yang Center for Measurement Standards Industrial Technology Research Institute/Taiwan
Content Selection of Wind Tunnel Calibration of A LDV Measuring Probe Implementation and Characteristics of A Wind Tunnel for Air-Speed Standard Estimation of Uncertainty for Anemometry Calibration
Type of Wind Tunnel Closed Circuit Wind Tunnel (CCWT) n directly re-circulate (low Power). n Noise is significantly lower. Open Circuit Wind Tunnels (OCWT) n Relatively small footprint n Low construction cost
Concerns of a wind tunnel Diffuser: Fan drive/Blower: provide a pressure increase flow, to to reach overcome Contraction to accelerate the flow of speed the Test section: Nozzle: to lower the flow speed, consequently reduce theanemometer pressure lossair inlevel the tunnel circuit. Steady driving force is mostly desirable in the test the turbulence provide desirable flow condition andsection, space forreduce calibration required. due to friction intensity.
Required flow fields in Wind tunnel test sections A uniform-flow, steady and low turbulence Restriction due to blockage effects n n Size effect that induce flow disturbance. Hard to estimate the uncertainty (a) ideal uniform flow (b) symmetric flow resulting fromwall friction
Timeline of air speed standard at CMS ’ 98 -’ 99: Small wind tunnel + a TSI LDV 2000: LDV Probe adjustment & calibration* Traceability of air-speed measurement Anemometry calibration Service 2003: Design a new wind tunnel with expanded LDV probe 2004: Implementation of new system *Optics and Lasers in Engineering, 38, 2002
Measurement Facilities-1 Wind tunnel : 1. Open-loop with expanded test section 2. Outlet of contraction nozzle: 200 mm 3. Motor controlled by a frequency converter 4. Designed air speed: ~30 m/s 5. Flow patterns simulated at test section
CFD simulation vs. LDV measurement Suction section Outlet of contraction nozzle Air LDV measurement velocity at 10 mm downstream LDV measurement velocity at 100 mm
Measurement Facilities-2 LDV : 1. TSI Probe 9832 with beam expander 2. Focal length: 450 mm 3. Nominal fringe spacing: 1. 921 m for beam of 514. 5 nm, 1. 822 m for 488 nm
Measurement Traceability of Anemometry Calibration Length Standard Vernier Caliper Frequency Standard (Time) Universal Counter Spinning Disc Check Anemometry Laser Doppler Anemometry + Wind tunnel Anemometry under Test
Spinning disc traceability Disc Pedestal -Disc eccentricity adjustable -Horizontal disc -rotary encoder for rotational speed - Local fringe spacing detectable
Obtain of Fringe Spacing Basics of calibration β Vldv= df f. D Vdisc= r cos df = r × / f. D× cos <1 degree Obtain local fringe spacing
Obtain of Fringe Spacing Comparison between (a) favorable and (b) improper Doppler bursts. Both the sequences show the change of burst signals when slightly moves the traverse stage.
Calibration of LDV Probe-1 Why is adjustment and calibration of LDV probe necessary? Measurement Volume df * *Miles, P. C. , ”Geometry of the Fringe Field Formed in the Intersection of Two Gaussian Beams, ” Applied Optics 1996; 35: 5887– 5895.
Calibration of LDV Probe-2 Step 1. Steer beams to optimize beam crossing Z=0 Z=1850 Z=1000 m m Change state of beam crossing Minimal variation of fringe spacing in measuring volume
Calibration of LDV Probe-3 Step 2. Determination of coefficient of air speed (coefficient of speed: mean fringe spacing) 1. Repeat measurement of fringe spacing at different rotation rates 2. Determined mean fringe spacing: 1. 9225 m with U= 0. 1%. (Nominal value: 1. 921)
Calibration of LDV Probe-4 Step 3. Evaluation of uncertainty of air-speed coefficient df = r × / f. D× cos + ε
Available region for installation of anemometry-probe Potential-core Region is considered for locating anemometry probe and was examined of its flow characterestics. Air flow d D X X = 100 mm D = 200 mm d = 80 mm (region I) 140 mm (region II) : region of interest : anemometry probe
Characteristics of Wind Tunnel Considered uncertainty sources of air speed measured by LDV in wind tunnel: 1. Characteristics of flow* A. Particle Lag B. Turbulence C. Velocity Bias (Sampling bias) D. Fringe Bias 2. Characteristics of wind tunnel A. steadiness & stability B. uniformity of velocity profiles C. variations of axial velocity *Ref. Fry, DTNSRDC, 1985
Uncertainty analysis of air speed in interested region Vtunnel : Air speed in wind tunnel Vldv : Measured air speed by LDV δ : correction factor due to flow characteristics ε : correction factor due to tunnel characteristics
Uncertainty due to Flow characteristics in interested region 1. Turbulence intensity Tu = 1. 73 % - 0. 81 % for V=0. 5 m/s – 25 m/s Measured at 100 mm downstream centerline of nozzle 2. Velocity bias (sampling effect) by comparing weighted (residence-time) with un-weighted velocities (Fry, 1985): , estimated to be < 0. 01%
Effects due to velocity distribution in interested region 1. Flow profiles along vertical radius (Z-axis flow uniformity) r (mm) V 1 (m/s) V 2 V 3 V 4 For region I: r = (-40 ~ 40) mm, X = (0~100)mm Standard Uncertainty = 0. 14 % Mean Std. Dev. (m/s) Rel. Std. Dev. % For region II: r = (-70 ~ 70) mm, X = (0~100)mm Standard Uncertainty = 0. 22 %
Effects due to velocity distribution in the interested region 2. Flow profiles along horizontal radius (Y-axis flow uniformity, the same process as 1. ) 3. Variation of velocities along flow direction (Xaxis flow uniformity) Std. dev. = 0. 129% (obtained from repeat measurement at different air speed)
Uncertainty analysis item Sources % νx 0. 050 9. 5 Flow Property Particle lag Velocity bias 0. 0557 0 0. 01 1066. 7 3 4 Turbulence int. Fringe bias Wind-tunnel Property 1 Velocity Profile (vertical axis) 0. 0548 0 Case A : 0. 2304 Case B : 0. 3474 Case A : 0. 1412 ∞ ∞ 999 ∞ 23. 9 26. 5 8 Case B : 0. 2245 Case A : 0. 1290 Case B : 0. 2319 0. 1284 Case A : 0. 2422 Case B : 0. 3554 Case A : 2. 074 Case B : 2. 059 Case A : 0. 50 14 4 7 9 23 25. 5 23 Case B : 0. 73 25. 5 LDV facility 1 2 2 Velocity Profile (horizonal) 3 V along x-axis Air speed in interested region k u(x i)/x i
Concluding Remarks Beams in LDV probe can be steered to reach optimal crossing Fringe spacing in measuring volume could be calibrated. n Expanded Uncertainty of df = 0. 1% Characteristics of wind tunnel dominate the measurement uncertainty. n n ie. Good wind tunnel is the key to calibration and measurement capability. For the present system, U = 0. 5% for air speed in region I, and U = 0. 73% in region II.
Comparison with other Lab.
Operation principle of RPTM module The spinning disc outputs a reference signal for tuning time delay. By superimposing the RPTM signal on the Doppler signals, a favorable burst can be frozen. Then, tuning the time delay and gate width to enclose interested region.
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