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Measurement of Atmospheric Icing and Droplets

Staffan Rydblom, Benny Thörnberg

2020IEEE Transactions on Instrumentation and Measurement10 citationsDOIOpen Access PDF

Abstract

Icing conditions including atmospheric liquid water content (LWC) and size distribution of droplets were recorded close to the top of Mt. Åreskutan, 1260-m above sea level, Sweden, a place known for frequent severe icing. The findings are comparatively analyzed. Combitech IceMonitor was used to measure the ice load, and HoloOptics T41 was used to measure the atmospheric icing rate. A method to translate the digital output from HoloOptics T41 to a value between 0 and 100 is described and used. Two instruments were used for measuring LWC and the median volume diameter (MVD). We created a model of icing intensity based on the k-nearest neighbor (KNN) using wind speed, LWC, and MVD as input. The result indicates that more learning data decrease the error. An heuristic model of erosion/ablation was added to simulate the ice load, and the result was compared with that of the standard Makkonen ice load model. The Makkonen model is suitable for estimating the ice load using a 1-h temporal resolution. With a 1-min temporal resolution, the erosion/ablation needs to be modeled and included. Our observations show that conditions can alternate between icing and erosion/ablation within 1 min during an icing event.

Topics & Concepts

IcingEnvironmental scienceWind speedMeteorologyWind tunnelIntensity (physics)ErosionVolume (thermodynamics)SnowIcing conditionsTemporal resolutionAtmospheric sciencesGeologyMechanicsPhysicsOpticsQuantum mechanicsPaleontologyIcing and De-icing TechnologiesCryospheric studies and observationsSmart Materials for Construction
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