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The “Monitor to measure the Integral TRAnsmittance” (MITRA)

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Presentation on theme: "The “Monitor to measure the Integral TRAnsmittance” (MITRA)"— Presentation transcript:

1 The “Monitor to measure the Integral TRAnsmittance” (MITRA)
and the “Cryogenic Solar Absolute Radiometer” (CSAR) IPC-XII Seminar, Davos, 12 October 2015 Benjamin Walter, Wolfgang Finsterle, Andre Fehlmann, Rainer Winkler, Ricco Soder, Markus Suter, Werner Schmutz

2 WRR SI MOTIVATION Direct Solar Irradiance measurements [W m-2]
traceable (Fehlmann et al. 2012) WRR internal stray light scale difference 0.34 % ± 0.09 % (k=1) Intercomparisons: SI

3 WRR SI MOTIVATION Direct Solar Irradiance measurements [W m-2]
traceable WRR CSAR = LINK directly traceable SI Intercomparisons SI - cryogenic radiometers

4 The MITRA Instrument Transmittance depends on solar spectrum which
changes with air mass and atmospheric conditions WSG World Standard Group CSAR = Cryogenic Solar Absolut Radiometer entrance window Monitoring of transmittance entrance window

5 Operation method & target uncertainty:
window IPC-XI uncertainty ≈ 1 % Previous uncertainty > 1 % sensing Measuring temperature rise Δt at both cavities reference cavity Target uncertainty for the CSAR: 0.01% (= 100 ppm) spectrally integrated transmittance  MITRA requirement: uncertainty of tint < 100 ppm

6 Measurements in front of the sun
WSG tracker  outdoor conditions HELIOSTAT  Laboratory conditions

7 Measurements in front of the sun
Laboratory: - instrument stability = 150 ppm = 0.015% - heliostat windows: wavelength dependent reflectivity Outdoor: - instrument stability = 900 ppm ≈ 0.1% - Measurement influenced by: wind / temperature variations Two questions: 1. How accurate is the absolute value? 2. How to reduce wind and temperature variation problems in outdoor measurements?

8 How accurate is the absolute value?  Periodical recalibration !
Temperature differences must be very accurate: no long term stability of parameters Δt measurement uncertainty < 0.1 mk no generally valid thermometer calibration possible  Periodical recalibration !

9 How accurate is the absolute value?
Measured offset to validated simulations of Fehlmann: ± 300 ppm (k = 1) Calculated offset: ppm Good agreement between measured and calculated offset to simulations  Periodical recalibration ± ppm (k = 1) depending on measurement conditions 2. wind and heat accumulation problem for outdoor measurements

10 WIND and HEAT ACCUMULATION:
10°C warmer relative to ambient air temperature

11 WIND and HEAT ACCUMULATION: Thermally-stable environment
wind cannot enter the cavity covered by the window wind influences both cavities similarly Thermally-stable environment wind shelter

12 Thermally-stable environment
No wind influences and Heat accumulation problems anymore electrical and thermal insulation Indirect cooling of MITRA - 6 Peltier elements - CPU fans - PID - controller Constant backplate temperature ≈ ± 0.1 K

13 Thermally-stable environment
Measurement on the WSG sun tracking platform ≈ 0.6 K Calibration of thermometers < ± 1 mK

14 Thermally-stable environment
Measurement on the WSG sun tracking platform ≈ 0.6 K ≈ ± 100 ppm

15 Thermally-stable environment
Measurement on the WSG sun tracking platform ≈ 0.6 K ≈ ± 100 ppm uncertainty =115 ppm mean(tint) = ≈ ± 100 ppm

16 Thermally-stable environment
Measurement on the WSG sun tracking platform ≈ ± 100 ppm uncertainty =165 ppm mean(tint) = ≈ ± 100 ppm

17 Summary MITRA improvements:
≈ ± 150 ppm Thermally-stable environment (Peltier cooling system)  Outdoor instrument stability ≈ 150 ppm (k = 1) Periodical recalibration of thermometers  Absolute value uncertainty about ppm (k = 1) 3. Overall uncertainty: ppm (k = 1)

18 Summary MITRA improvements:
≈ ± 150 ppm Promising results Future improvements to reach the 100 ppm goal: Three cavity design to monitor the temperature drift Liquid cooling of the instrument Larger heatsink to provide more stable conditions

19 Cryogenic Solar Absolute Radiometer (CSAR)
Cryocooler (Helium) 20 K reference block quartz window 10 mm cavity View limiting aperture apertures

20 Cryogenic Solar Absolute Radiometer
Measurement procedure: Cleaning the windows One day for cooling CSAR to 20K Cavity characterization Electrical measurements every min Sampling rate = 3 s MITRA Helium pipes

21 Cryogenic Solar Absolute Radiometer
IPC-XII DAY: CSAR measures about % lower than WRR

22 Cryogenic Solar Absolute Radiometer
( k = 2 ) IPC-XII Good agreement with previous findings of difference between the WRR and the SI scales. Detailed values and uncertainties will follow soon ...

23 Thank you for your attention! SUMMARY
MITRA: Thermally-stable environment (Peltier system) a.) No wind influences / convection / heat accumulation b.) Strongly reduce temperature drift c.) Remaining drift can empirically be corrected for d.) Periodical recalibration of thermometers d.) MITRA uncertainty ≈ ppm (k = 1) CSAR: a.) Overal stable performance b.) Preliminary results are in good agreement with previous findings that the SI scale is about 0.2% - 0.3% lower than WRR Thank you for your attention!

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