Core Lab operates a full service geomechanics laboratory that provides our clients with test data and
unmatched engineering analyses to predict borehole stability. Detailed characterization of wellbore
stability offers important solutions to both drilling and production phase problems that cost the industry
Core Lab's geomechanics lab is the most extensive facility of its kind. Triaxial rock testing measures rock
strength and mechanical properties under various conditions. This information is valuable for reliably
predicting borehole stability and for accurately calibrating dipole sonic logs.
The thick-wall cylinder test employs a geometry that simulates actual loading conditions under downhole stresses.
This provides direct measure of pressures under which a hole will start producing sand or cause other problems
like casing collapse. Armed with this information, an operator can control conditions to maintain wellbore stability.
Unconfined compressive strength (UCS) logs are established using ultrasound to probe relative strength along a
large depth interval of core. This test inexpensively locates important sections of rock for advanced triaxial
Mohr-Coulomb analyses provide formation cohesion (initial shear strength) and angle of internal friction. These
are necessary parameters for reliable wellbore stability prediction, and are not measured with logs.
Compressive strengths from a series of triaxial compressive tests are plotted in order to determine the critical
shear stress and predict conditions for hydraulic fracturing and borehole breakouts.
Dipole sonic logs are often found to be inaccurate for predicting borehole stability in many reservoirs. These
inaccuracies cause engineering failures including poor fracture designs and unreliable wellbore stability analyses.
Static lab data are required for a reliable wellbore stability analysis and accurate calibrations of dipole sonic logs.
These analyses have been successfully applied to hundreds of wells worldwide in many different types of reservoirs.