Acoustic waveforms from long-and short-spaced sonic logs were investigated to determine if shortspaced tools give accurate measurements of shear wave velocity. Compressional wave interference can affect shear velocities from both tools adversely. However, the short-spaced tool was useful over a wider range of conditions.
Acoustic waveform amplitudes (compressional, shear, and later arrivals) and patterns of reflected and mode converted waves recorded on an axially oriented acoustic logging tool are unreliable indicators of in-situ fractures in Altamont Field, UT. These negative results are believed to result fromvertical travel path of the acoustic waves, whereby vertical fractures provide negligible interruption to the path, andtool frequency. Introduction Following the discovery of Altamont Field in the Uinta Basin of Utah in 1970, Shell Research initiated a program to investigate ways to locate fractured zones effectively. Location of fractures was considered important since the reservoir at Altamont Field is very tight sandstone and carbonate that requires fractures for commercial transmissibility of fluids. While many techniques for detecting fractures have been proposed and tested, no commercial tool is available that can accurately and consistently respond to fractured zones. Fractures at Altamont Field are usually vertical or almost vertical. The vertical traveling acoustic energy detected by conventional sonic logs is probably less sensitive to vertical fractures than to horizontal ones. Three proposed means for deterring these vertical fractures were selected for further study. One proposal (described by Vogel) was to use circumferentially traveling shear waves that, in vertically fractured zones, would require recorded signals to cross the fracture plane. At our request, a prototype tool was built by Schlumberger (their Circumferential Microsonic Log - CMS log). Results of field tests of this tool have indicated that it is a viable way to locate vertically oriented fractures. The second proposed method was to measure amplitudes of the low-frequency boundary wave traveling along the borehole wall between transmitter and receiver of an axially oriented array. The third proposal was to investigate patterns of reflected or mode converted energy that may originate from acoustic discontinuities, such as fractures or bed boundaries. These last two proposed methods were investigated and the results are reported in this study. Amplitudes of compressional (P) and shear (S) waves also were measured since they were readily available from the same wave forms used for studying boundary wave amplitudes and interference patterns. Procedures Procedures A single-transmitter/single-receiver acoustic tool with about 70-in. transmitter-receiver (T-R) spacing was run in two cored wells at Altamont Field. The data were recorded on the field film in a conventional variable density (X-Z) presentation and all wave forms were recorded on magnetic tape for laboratory processing. The tapes were played back in the laboratory and the data were displayed on an oscilloscope. A 35-mm, continuous time drive camera was attached to the face of the scope. By varying tape and film speed, suitable presentations were obtained for measuring amplitudes and observing interference patterns. Peak-to-peak measurements of compressional, shear, and boundary wave amplitudes were made every 6 in. through cored intervals of the two wells. These data were keypunched, normalized, and played back as amplitude curves on a flatbed plotter. played back as amplitude curves on a flatbed plotter. Amplitude curves were correlated with borehole logs and core depth, and the data were examined for relative amplitude attenuation in the fractured zones. A considerably different display was required for studying interference patterns. JPT P. 1199
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
customersupport@researchsolutions.com
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.