The Scratch Test is a relatively new technique for determination of mechanical properties of rocks. In a Scratch Test, the surface of the rock is scratched at constant depth (typically less than 1 mm) by a sharp cutter, while the applied forces are being monitored. It is found that these forces are closely related to the mechanical properties of the rock. The Scratch Test thus represents a direct measure on the core material, and provides continuous coverage of data for the entire length of available core material. The work reported here is a detailed study of the Scratch Test as a technique for determining strength and elastic properties of sedimentary rocks. The work is based on extensive laboratory testing of many sedimentary rocks with different mechanical properties. The results of the study show that parameters obtained in a Scratch Test, in particular the Specific Energy, correlate very well with the Uniaxial Compressive Strength (UCS). The accuracy of the Scratch Test for rock strength determination is seen to be at least comparable to the accuracy of the UCS Test, while the resolution is even better. It is also found that the Scratch Test may be used to determine the elastic modulus of rocks with good precision. The Scratch Test only requires access to a free surface of the rock. Hence, it may be run on most available core material. Provided that the core is in a reasonably good shape, no special preparation is required for the test, which is thus both quick and cheap. Unlike the UCS Test, the Scratch Test is almost non-destructive, and provides continuous data coverage. The Scratch Test is therefore a very attractive method for determination of stiffness and strength of core materials when addressing issues like reservoir compaction, hydraulic fracturing, borehole stability and sand production, offering a better resolution and data coverage than any other technique available today. Rock mechanical parameters derived from wire-line log data are continuous but have the disadvantage of being derived indirectly from other measurements, such as sonic velocity, density and porosity. Introduction Rock mechanical parameters of underground formations are required when addressing issues involving reservoir compaction, hydraulic fracturing, borehole stability and sand production. These parameters are primarily obtained along reservoir sections, even though data from the overburden also are needed in many applications. Laboratory measurements of field cores provide a direct determination of these parameters, but they yield only information at a limited number of locations along the wellbore, since the test methods require a significant amount of material. Rock mechanical parameters derived from wire-line log data are, on the other hand, continuous, but have the disadvantage of being derived indirectly from other measurements, such as sonic velocity, density and porosity. The scratch test may solve some of the problems related to laboratory measurements on field cores and wire-line logging tools: It is quick, cheap and continuous, requires significantly less rock material than ordinary laboratory testing for rock characterisation, and represents a direct measurement of rock mechanical parameters. Laboratory scratch measurements on field cores have the potential of increasing the amount of rock mechanical data from cores, since the test technique is continuous.
In this study, hydrates were generated in synthetic sediments in a laboratory cell. After hydrate formation took place and the sediment solidified, the samples were investigated both visually and by the use of nuclear magnetic resonance (NMR) imaging. The hydrates in this initial study were formed from model systems at low pressure. The results show hydrates distribution effects. Scans in the NMR apparatus were also made of the unfrozen samples to serve as a basis for comparison. NMR here maps the mobility of hydrogen atoms and their distribution in a sample. The relevant factor is the density of mobile H‐atoms, and this is shown to be about five times smaller for a volume of (for example) tetrahydrofuran (THF, C4H8O) hydrate than for the fluids of water and/or THF. This correlates very well with an observed signal decrease by a factor of six in an NMR‐studied sample after hydrate formation had taken place.
The mechanical behavior of some Adriatic soft weak reservoir rocks obtained from cores is characterized taking into account water saturation effects. The characterization includes triaxial compression, and uniaxial strain (oedometric) tests, as well as water injection tests under reservoir conditions. From the experimental results, a uniaxial strain compaction model for weak rocks is calibrated for use in reservoir compaction studies in the Adriatic Sea area. A porosity-dependent elastoplastic model is used to capture the variation of compaction in the materials in the reservoir zone. P. 411
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