Physical Mechanisms Controlling the Strength-Deformation Behavior of Frozen Sand: I

A high-pressure low-temperature triaxial compression testing system with on specimen axial strain measurements and lubricated end plattens was developed in order to measure the stress-strain-volume change behavior of frozen Manchester Fine Sand (MFS) from very small (0.01%) to very large (25%) axial...

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Bibliographic Details
Main Authors: Andersen, Glen R., Germaine, John T., Ladd, Charles C., Swan, Chris W.
Other Authors: MASSACHUSETTS INST OF TECH CAMBRIDGE DEPT OF CIVIL ENGINEERING
Format: Text
Language:English
Published: 1992
Subjects:
Soil Mechanics
Snow
Ice and Permafrost
*SAND
*ICE MECHANICS
*FROZEN SOILS
*SOIL TESTS
TEST AND EVALUATION
COMPRESSION
STRESS STRAIN RELATIONS
DENSITY
MEASUREMENT
TEMPERATURE
VOLUME
LOW TEMPERATURE
YIELD STRENGTH
BEHAVIOR
PRESSURE
ICE
SOILS
STRAIN RATE
STRENGTH(MECHANICS)
SENSITIVITY
STRAIN(MECHANICS)
FINES
SHEAR STRENGTH
HARDENING
MODELS
MATERIALS
COMPOSITE MATERIALS
DEFORMATION
MODULUS OF ELASTICITY
HIGH PRESSURE
COLD REGIONS
COMPRESSION TESTS
COMPRESSIVE STRENGTH
AXIAL LOADS
TRIAXIAL COMPRESSION
TRIAXIAL STRESSES
MANCHESTER FINE SAND
Ice
permafrost
Online Access:http://www.dtic.mil/docs/citations/ADA253903
http://oai.dtic.mil/oai/oai?&verb=getRecord&metadataPrefix=html&identifier=ADA253903
Description
Summary:A high-pressure low-temperature triaxial compression testing system with on specimen axial strain measurements and lubricated end plattens was developed in order to measure the stress-strain-volume change behavior of frozen Manchester Fine Sand (MFS) from very small (0.01%) to very large (25%) axial strains. The main testing program was conducted at a temperature of T=-9.5 deg C and varied the relative density from 20 to 100%, the confining pressure from 0.1 to 10 MPa, and the strain rate from 0.000003/sec (slow) to 0.0004/sec (fast). These data show a constant Young's modulus that can be explained in terms of a composite materials model; provide the first detailed evaluation of the upper yield stress, which is essentially independent of sand density and confining pressure, and has a rate sensitivity similar to that of granular ice; and show that the peak strength generally increases linearly with sand density, increases nonlinearly with confinement, and has a rate sensitivity much less than granular ice. Initial tests at different temperatures indicate a larger temperature sensitivity than predicted for granular ice. A similar triaxial system was used to measure the stress-strain behavior of unfrozen MFS as a function of relative density and confining pressure. These data are used to evaluate Ladanyi's dilatancy-hardening model developed to predict the strength of frozen sand.

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