Design for Navigation Improvements at Nome Harbor, Alaska Coastal Model Investigation

A 1:90-scale (undistorted) three dimensional coastal hydraulic model was used to investigate the design of proposed navigation improvements at Nome Harbor, Alaska, with respect to wave, current, and shoaling conditions at the site. The model reproduced about 3,350 m (11,000 ft) of the Alaskan shorel...

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Bibliographic Details
Main Authors: Bottin, Robert R., Jr., Acuff, Hugh F.
Other Authors: ARMY ENGINEER WATERWAYS EXPERIMENT STATION VICKSBURG MS
Format: Text
Language:English
Published: 1998
Subjects:
Test Facilities
Equipment and Methods
Fluid Mechanics
Geography
Marine Engineering
*ALASKA
*MARINE TRANSPORTATION
*HYDRAULIC MODELS
*HARBOR MODELS
CONTROL SYSTEMS
COASTAL REGIONS
AUTOMATION
MATERIALS
SITES
ENERGY
TURBULENCE
LININGS
BATHYMETRY
SEDIMENT TRANSPORT
SPECTRA
NAVIGATION
VERTICAL ORIENTATION
INTERNAL
OPERATION
STORMS
DATA ACQUISITION
PATTERNS
WALLS
EXTERNAL
GENERATORS
ADAPTERS
ROUGHNESS
HEIGHT
CHANNELS
BREAKWATERS
DOCKS
WAVES
TRACE ELEMENTS
OFFSHORE
COAL
CAUSEWAYS
NOME(ALASKA)
Norton Sound
Nome
Alaska
Online Access:http://www.dtic.mil/docs/citations/ADA354454
http://oai.dtic.mil/oai/oai?&verb=getRecord&metadataPrefix=html&identifier=ADA354454
Description
Summary:A 1:90-scale (undistorted) three dimensional coastal hydraulic model was used to investigate the design of proposed navigation improvements at Nome Harbor, Alaska, with respect to wave, current, and shoaling conditions at the site. The model reproduced about 3,350 m (11,000 ft) of the Alaskan shoreline, the existing harbor and lower reaches of the Snake River, and sufficient offshore bathymetry in the Norton Sound to permit generation of the required experimental waves. The model was used to determine the impacts of a new entrance channel on wave-induced current patterns and magnitudes, sediment transport patterns, and wave conditions in the new channel and harbor area, as well as to optimize the lengths and alignments of new breakwaters and causeway extensions. A 24.4-m-long (9O-ft-1ong) unidirectional, spectral wave generator, and automated data acquisition and control system, and a crushed coal tracer material were utilized in model operation. It was concluded from study results that: a) existing conditions are characterized by rough and turbulent wave conditions in the existing entrance. Very confused wave patterns were observed in the entrance due to wave energy reflected off the vertical walls lining the entrance. Wave heights in excess of 1.5 m (5 ft) were obtained in the entrance for typical storm conditions; and wave heights of almost 3.7 m (12 ft) were obtained in the entrance for 5O-year storm wave conditions with extreme high-water level (4 m (+13 ft); b) wave conditions along the vertical-faced causeway docks were excessive for existing conditions. Wave heights in excess of 3.7 and 2.7 m (12 and 9 ft) were obtained along the outer and inner docks, respectively, for typical storm conditions; and wave heights of almost 7 and 5.8 m (23 and 19 ft) were recorded along these docks, respectively, for 5-year storm wave conditions with extreme high-water levels.

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