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Piezoelectric precipitation sensor from VAISALA

Piezoelectric precipitation sensor from VAISALA. Atte Salmi Project Manager Vaisala Instruments. Contents. Construction of the sensor Measurement method Sensor calibration Errors in measurement method Field test results Conclusions. Introduction. Developed for Weather Transmitter

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Piezoelectric precipitation sensor from VAISALA

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  1. Piezoelectric precipitation sensor from VAISALA Atte Salmi Project Manager Vaisala Instruments

  2. Contents • Construction of the sensor • Measurement method • Sensor calibration • Errors in measurement method • Field test results • Conclusions

  3. Introduction • Developed for Weather Transmitter • Durable and maintenance free

  4. Vaisala RAINCAPConstruction

  5. Vaisala RAINCAPMeasurement method • The voltage output U(t) from the piezo detector due to a drop impact is proportional to the volume of the drop. • Since, the surface area is known, the drop signals can be directly converted to accumulated precipitation.

  6. Terminal velocity Atlas et. al. (1973): vt (D) = 9.65 - 10.30e(0.6D)

  7. Vaisala RAINCAPType calibration Precipitation P = f(U) • Comparison of detector voltage response with precipitation readings from accurate reference instruments under different field conditions: • light and moderate rain in Finland • moderate and heavy rain in Malaysia

  8. Errors in measurement method Vaisala RAINCAP do not have systematic error sources like: wetting on the internal walls of the collector and the container evaporation from the container splashing of water in and out Error sources related to Vaisala RAINCAP are more stochastic than systematic: variation in the shape and velocity of raindrops caused by air movements sensitivity variations over the sensor area, due to surface wetness

  9. Results - Kuala Lumpur, Malaysia

  10. Results - FMI Observatory, Jokioinen Total accumulations during a four months test period at Jokioinen observatory.

  11. Results - Tokyo University, Japan

  12. Results - characteristic short-interval data

  13. Conclusions • Due to the measurement method and construction of the sensor, the Vaisala RAINCAP is virtually maintenance free. The sensor does not suffer from systematic errors due to wetting, evaporation or splashing of raindrops. It is also capable for true real time intensity measurement. • The field results show good comparability of the sensor to traditional tipping buckets and weighing-recording gauges. • Because of its robust design with no moving parts the Vaisala RAINCAP is especially suitable for dense measurement networks.

  14. Contact Information • Atte Salmi • Project Manager • Vaisala Instruments • Phone +358 9 8949 2785 • atte.salmi@vaisala.com

  15. Errors in precipitation measurement where Pk is the adjusted amount of precipitation, Pg the recorded precipitation in the gauge, k and P1 - P4 the adjustments for different error components listed in Table below and Prrandom observational and instrumental error. World Meteorological Organization, 2000: Precipitation Estimation and Forecasting, Point Measurement Using Gauges. Operational Hydrology Report No. 46, WMO-No. 887, Geneva.

  16. Four operation modes • Precipitation Start/End mode: • Transmitter sends automatically a precipitation message 10 seconds after the recognition of the first drop. The messages are sent continuously as the precipitation proceeds and stopped when the precipitation ends. • Tipping bucket mode: • This mode emulates tipping bucket type precipitation sensors. Transmitter sends automatically a precipitation message when the counter detects one unit increment (0.1 mm/0.01 in). • Time mode: • Transmitter sends automatically a precipitation message in the update intervals defined by the user. • Polled mode: • Transmitter sends a precipitation message whenever requested by the user.

  17. Piezoelectric sensor • When mechanical pressure is applied to the sensor, the crystalline structure produces a voltage U(t) proportional to the pressure. Conversely, when an electric field is applied, the structure changes shape producing dimensional changes in the material. where c is a constant dependent on the properties of the piezoelectric material.

  18. Vaisala RAINCAP Hail Rain drop

  19. Drop signal

  20. Drop signal t2 t1

  21. Drop collapse t2 t1

  22. Technical data PTU

  23. Technical data liquid precipitation

  24. Technical data wind

  25. Technical data general

  26. Technical data general

  27. The Rain Lab

  28. Photoacoustic principle

  29. Interface Architecture Standard ASCII Terminal NMEA 0183 v3.0 Talker SDI-12 v1.3 Receiver system level data formattransmission ASCII Polled / Automatic ASCIIPolled HW- interface RS232, RS485/422 3-wire SDI-12 instrument level External power supply5 - 30 VDC

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