Ice Construction--Bottom Freezing Techniques for Constructing Shore and Near-Shore Ice Structures.

New methods and equipment for thickening and strengthening natural sea ice are needed to advance polar operational capabilities. Of the basic categories of techniques for inducing ice growth (ice injection, cold fluid injection, and recirculating fluid), one recirculation technique-the convection ce...

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Bibliographic Details
Main Author: Culbertson, T. L.
Other Authors: NAVAL CIVIL ENGINEERING LAB PORT HUENEME CA
Format: Text
Language:English
Published: 1971
Subjects:
Snow
Ice and Permafrost
Civil Engineering
Structural Engineering and Building Technology
(*SEA ICE
FREEZING)
(*STRUCTURES
SEA ICE)
ICE
CRYSTAL GROWTH
THICKNESS
STABILITY
CONVECTION(HEAT TRANSFER)
SEA WATER
ATMOSPHERIC TEMPERATURE
SOLAR RADIATION
ALASKA
COASTAL REGIONS
COLD WEATHER CONSTRUCTION
ICE FORMATION
*ICE CONSTRUCTION
POINT BARROW
Balch
Construction Point
Barrow
Ice
permafrost
Point Barrow
Sea ice
Alaska
Online Access:http://www.dtic.mil/docs/citations/AD0889704
http://oai.dtic.mil/oai/oai?&verb=getRecord&metadataPrefix=html&identifier=AD0889704
Description
Summary:New methods and equipment for thickening and strengthening natural sea ice are needed to advance polar operational capabilities. Of the basic categories of techniques for inducing ice growth (ice injection, cold fluid injection, and recirculating fluid), one recirculation technique-the convection cell-was found to best fulfill the requirements for polar applications. Other techniques imposed greater work or energy requirements. Two basic convection cell systems were laboratory tested: liquid convection and liquid-vapor phase convection. At a 30F air temperature, the Balch liquid convection cell produced 7.75 inches of ice in 90 hours while the Long liquid-vapor phase cell produced only 2 inches during the same time period. Because the liquid convection cell was found to be more effective at the mean polar air test temperatures than the two-phase cell, it was selected for field testing at Point Barrow, Alaska. The initial field tests at Point Barrow during the spring of 1969 demonstrated the excellent potential of the Balch-type liquid convection cell for thickening, stabilizing, and anchoring near-shore ice structures. Cells suspended in seawater produced ice along the entire submerged length; the production rate was dependent on the seawater temperature, the prevailing air temperature, and the thickness of the ice mass around the cell. In FY70 convection cells were used to form two grounded ice structures offshore at Point Barrow to permit study of their long-term stability. Laboratory research to improve cell performance and field application has resulted in the development of two new liquid convection cells: a simplified vertical convection cell and a horizontal convection cell. (Author)

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