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ARCHIVED REPORTS_2006_4
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ARCHIVED REPORTS_2006_4
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Last modified
7/17/2020 3:53:24 PM
Creation date
7/3/2020 10:51:54 AM
Metadata
Fields
Template:
EHD - Public
ProgramCode
4400 - Solid Waste Program
File Section
ARCHIVED REPORTS
FileName_PostFix
2006_4
RECORD_ID
PR0440005
PE
4433
FACILITY_ID
FA0004516
FACILITY_NAME
FORWARD DISPOSAL SITE
STREET_NUMBER
9999
STREET_NAME
AUSTIN
STREET_TYPE
RD
City
MANTECA
Zip
95336
APN
20106001-3, 5
CURRENT_STATUS
01
SITE_LOCATION
9999 AUSTIN RD
P_LOCATION
99
P_DISTRICT
004
QC Status
Approved
Scanner
SJGOV\rtan
Supplemental fields
FilePath
\MIGRATIONS\SW\SW_4433_PR0440005_9999 AUSTIN_2006_4.tif
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EHD - Public
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4:0 SOIL ARCHING <br />In 1936 Karl P Terza hi published his seminal work on soil arching. The University of <br />B g Y <br />Florida performed an extensive series of experiments further defining the mechanics of soil <br />arching in 1961. At the Waterways Experiment Station (WES), the U.S. Army Corps of <br />Engineers (USACE) performed a comprehensive set of large scale arching experiments in <br />1965. Each study supports and refines the work and conclusions carried forward from <br />previous experiments. A brief, simplified overview of some of the conclusions found in <br />these reports follows: <br />• When the bearing pressure below a soil is removed (the large scale experiments <br />utilized a trapdoor configuration), the soil will arch over a cavity centered at the <br />midpoint of the yielding zone. <br />• The pressure over the yielding zone (trap door) will be less than the average <br />vertical stress due to the weight of the soil layer. <br />• The pressure immediately outside the perimeter of the yielding zone will be <br />greater than the average vertical stress due to the weight of the soil layer. <br />• This arching condition is permanent. <br />•Above a given height (the apex of the arch), all loads whether they be from the <br />weight of soil or from a surcharge will arch around the cavity and have no impact <br />on the pressures measured immediately above the yielding zone. <br />• 3-dimensional arching (yielding zone in the shape of a circle) is more efficient <br />than 2-dimensional arching (yielding zone in the shape of an infinitely long <br />trench). <br />• The pressure over the yielding zone is equal to the weight of the mass within the <br />arch, if the height of the soil (and waste) exceeds the apex of the arch. <br />• The dimensions of the cavity formed by the arch are dependent on the soil strength. <br />• The approximate shape of the arch is triangular rather than spherical. As a result, <br />a yielding zone in the shape of a circle would produce an archin the shape of a <br />cone rather than a half sphere. <br />The subsidence model provides the geometry necessary to analyze the arching <br />phenomenon. The data collected in the experiments discussed above allows one to predict <br />the normal force transferred to the geosynthetic reinforcing material within the landfill <br />liner system. <br />(3) <br />
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