Optimization of Snow Drifting Mitigation and Control Methods for Iowa Conditions

The present study proposes a joint experimental and numerical approach to monitor snow deposits around snow fences, quantitatively estimate snow deposits in the field, asses the efficiency and improve the design of snow fences. Snow deposit profiles were mapped using GPS based real-time kinematic surveys (RTK) conducted at the monitored field site during and after snow storms. The monitored site allowed testing different snow fence designs under close to identical conditions over four winter seasons. The study also discusses the detailed monitoring system and analysis of weather forecast and meteorological conditions at the monitored sites. A main goal of the present study was to assess the performance of lightweight plastic snow fences with a lower porosity than the typical 50% porosity used in standard designs of such fences. The field data collected during the first winter was used to identify the best design for snow fences with a porosity of 50%. Flow fields obtained from numerical simulations showed that the fence design that worked the best during the first winter induced the formation of an elongated area of small velocity magnitude close to the ground. This information was used to identify other candidates for optimum design of fences with a lower porosity. Two of the designs with a fence porosity of 30% that were found to perform well based on results of numerical simulations were tested in the field during the second winter along with the best performing design for fences with a porosity of 50%. Field data showed that the length of the snow deposit away from the fence was reduced by about 30% for the two proposed lower-porosity (30%) fence designs compared to the best design identified for fences with a porosity of 50%. Moreover, one of the lower-porosity designs tested in the field showed no significant snow deposition within the bottom gap region beneath the fence. Thus, a major outcome of this study is to recommend using plastic snow fences with a porosity of 30%. It is expected that this lower-porosity design will continue to work well for even more severe snow events or for successive snow events occurring during the same winter. The approach advocated in the present study allowed making general recommendations for optimizing the design of lower-porosity plastic snow fences. This approach can be extended to improve the design of other types of snow fences. Some preliminary work for living snow fences is also discussed. Another major contribution of this study is to propose, develop protocols and test a novel technique based on close range photogrammetry (CRP) to quantify the snow deposits trapped snow fences. As image data can be acquired continuously, the time evolution of the volume of snow retained by a snow fence during a storm or during a whole winter season can, in principle, be obtained. Moreover, CRP is a non-intrusive method that eliminates the need to perform man-made measurements during the storms, which are difficult and sometimes dangerous to perform. Presently, there is lots of empiricism in the design of snow fences due to lack of data on fence storage capacity on how snow deposits change with the fence design and snow storm characteristics and in the estimation of the main parameters used by the state DOTs to design snow fences at a given site. The availability of such information from CRP measurements should provide critical data for the evaluation of the performance of a certain snow fence design that is tested by the IDOT. As part of the present study, the novel CRP method is tested at several sites. The present study also discusses some attempts and preliminary work to determine the snow relocation coefficient which is one of the main variables that has to be estimated by IDOT engineers when using the standard snow fence design software (Snow Drift Profiler, Tabler, 2006). The authors' analysis showed that standard empirical formulas did not produce reasonable values when applied at the Iowa test sites monitored as part of the present study and that simple methods to estimate this variable are not reliable. The present study makes recommendations for the development of a new methodology based on Large Scale Particle Image Velocimetry that can directly measure the snow drift fluxes and the amount of snow relocated by the fence.

• Record URL:
  http://publications.iowa.gov/19046/1/IADOT_UI_IHRB_TR-626_Optimization_Snow_Drifting_Mitigation_2015_r.pdf
• 
• Record URL:
  https://rosap.ntl.bts.gov/view/dot/66876
• Corporate Authors:

  Institute for Transportation, Iowa State University

  ,    

  University of Iowa, Iowa City

  Department of Civil and Environmental Engineering
  Iowa City, IA  United States  52242

  Iowa Department of Transportation

  Ames, IA  United States  50010

  Bridge Engineering Center

  ,    

  Iowa Highway Research Board

  800 Lincoln Way
  Ames, IA  United States  50010

  Federal Highway Administration

  1200 New Jersey Avenue, SE
  Washington, DC  United States  20590
• Authors:
  • Constantinescu, George
  • Muste, Marian
  • Basnet, K
• Publication Date: 2015-2-9

Language

• English

Media Info

• Media Type: Web
• Edition: Final Report
• Features: Figures; Photos; Tables;
• Pagination: 122p

Subject/Index Terms

• TRT Terms: Fluid dynamics; Highway safety; Monitoring; Optimization; Photogrammetry; Photogrammetry; Snow and ice control; Snow fences; Snowdrifts; Winter maintenance
• Identifier Terms: Iowa Department of Transportation
• Geographic Terms: Iowa
• Subject Areas: Highways; Maintenance and Preservation; Safety and Human Factors;

Filing Info

• Accession Number: 01689337
• Record Type: Publication
• Contract Numbers: TR-626 1 80224 00
• Files: NTL, TRIS, ATRI, USDOT, STATEDOT
• Created Date: Dec 20 2018 3:32PM