1. An Assessment of Three Different In Situ Oxygen Sensors for Monitoring Silage Production and Storage
- Author
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Kai-Benjamin Schütt, Peter Boeker, Haiyang Zhou, Menghua Li, Daokun Ma, Wolfgang Buescher, Peter Schulze Lammers, Yurui Sun, Qiang Cheng, Guilin Shan, Kerstin H. Jungbluth, and Christian Maack
- Subjects
In situ ,Silage ,oxygen (O2) ,carbon dioxide (CO2) ,galvanic oxygen cell (GOC) ,Clark oxygen electrodes (COE) ,Dräger chip measurement system (DCMS) ,silage ,Analytical chemistry ,chemistry.chemical_element ,lcsh:Chemical technology ,01 natural sciences ,Biochemistry ,Oxygen ,Article ,Analytical Chemistry ,chemistry.chemical_compound ,Galvanic cell ,lcsh:TP1-1185 ,Electrical and Electronic Engineering ,Instrumentation ,Electrodes ,Chemistry ,System of measurement ,010401 analytical chemistry ,Agriculture ,04 agricultural and veterinary sciences ,Equipment Design ,Carbon Dioxide ,Atomic and Molecular Physics, and Optics ,0104 chemical sciences ,Carbon dioxide ,Calibration ,040103 agronomy & agriculture ,Dry ice ,0401 agriculture, forestry, and fisheries ,Electronics ,Oxygen sensor - Abstract
Oxygen (O2) concentration inside the substrate is an important measurement for silage-research and-practical management. In the laboratory gas chromatography is commonly employed for O2 measurement. Among sensor-based techniques, accurate and reliable in situ measurement is rare because of high levels of carbon dioxide (CO2) generated by the introduction of O2 in the silage. The presented study focused on assessing three types of commercial O2 sensors, including Clark oxygen electrodes (COE), galvanic oxygen cell (GOC) sensors and the Dräger chip measurement system (DCMS). Laboratory cross calibration of O2 versus CO2 (each 0–15 vol.%) was made for the COE and the GOC sensors. All calibration results verified that O2 measurements for both sensors were insensitive to CO2. For the O2 in situ measurement in silage, all O2 sensors were first tested in two sealed barrels (diameter 35.7 cm; height: 60 cm) to monitor the O2 depletion with respect to the ensiling process (Test-A). The second test (Test-B) simulated the silage unloading process by recording the O2 penetration dynamics in three additional barrels, two covered by dry ice (0.6 kg or 1.2 kg of each) on the top surface and one without. Based on a general comparison of the experimental data, we conclude that each of these in situ sensor monitoring techniques for O2 concentration in silage exhibit individual advantages and limitations.
- Published
- 2015