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Tensiometers Then and Now. Elizabeth Scherling BAE 558 Semester Project Spring 2005. Outline. Theory Components Historical Devices Applications Modern Devices Applications Calibration Maintenance Challenges Future Tensiometers. Theory.
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TensiometersThen and Now Elizabeth Scherling BAE 558 Semester Project Spring 2005
Outline • Theory • Components • Historical Devices • Applications • Modern Devices • Applications • Calibration • Maintenance • Challenges • Future Tensiometers
Theory • Tensiometers directly measure soil water matric potential • Forces responsible for capillary action and water retention • van der Waals • Electrostatic dipole • Osmotic forces • Surface tension
Components I • Thin-walled porous cup • Rigid body • Pressure gauge • Mechanical • Electrical: pressure transducer • Hydraulic: manometer • De-aired water
Components II Porous Cup Body Pressure Gauge
Historical Devices I • B. E. Livingston • 1908 • Earliest account of a tensiometer-like device
Historical Devices II • H. E. Pulling and B. E. Livingston • 1915 • Measured what they called the “water supplying power of the soil”
Historical Devices III • C. J. Lynde and H. A. Dupre • 1913 • First hanging column design • Measured what they called the “capillary lift of soil”
Historical Applications • Irrigation control • Auto-irrigation for potted plants • Capillary pressure measurement
Modern Devices I • J. M. Hubbell and J. B. Sisson • 1998 • Advanced tensiometer design
Modern Devices II • B. Lebeau, S. Barrington, and R. Bonnell • 2003 • Micro-tensiometer
Modern Applications • Irrigation Control • Greenhouse • Farm • Field • Vadose Zone Studies • Transport Research • Ultimately: Tensiometers have the potential to save water and reduce infiltration contamination
Calibration • The tensiometer must be subjected to known positive and negative pressures. • U-tube manometer • Vacuum chamber • Recalibration only recommended after long periods of inactivity.
Maintenance • Gas Evolution • De-air water prior to filling and for subsequent water replacement • Vacuum, autoclave, or boil • Check for bubbles frequently in simple designs • Add water regularly for advanced designs • Maintain intimate contact between porous cup wall and soil matrix
Challenges I Choosing the correct tensiometer Hubbell and Sisson, 1998
Challenges II Weather Conditions Cloudy day Sunny day Hansen and Pasian, 1999
Challenges III Limited Matric Potential Ranges • Low range: 3 to 6 kPa • Controlled and reliable • Medium range: 9 to 12 kPa • Not stable or reliable • High range: 15 to 18 kPa • Not stable or reliable From a study by Hansen and Pasian, 1999 Low Range Medium Range High Range
Future Tensiometers • For long duration in situ use: • Cost effective advanced tensiometers • For large-scale greenhouse use: • Micro-tensiometers with greater control of large ranges of moisture tension