| Title |
FRACTURE MAPPING IN GEOTHERMAL FIELDS WITH LONG-OFFSET INDUCTION LOGGING |
| Authors |
Michael Wilt, Shinji Takasugi, Toshlhiro Uchida, Paul Kasameyer, Ki Ha Lee, Marcelo Lippmann |
| Year |
1997 |
| Conference |
Stanford Geothermal Workshop |
| Keywords |
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| Abstract |
The mapping of producing fractures in a geothermal field is an important technical objective in field development. Locating, orienting, and assessing�producing fractures can guide drilling programs and optimize the placement of production and injection wells. A long-offset multicomponent borehole induction resistivity tool capable of surviving the high temperatures encountered in geothermal wells has recently been developed in a NEDO project ìDeep seated Geothermal Resource Surveyíí and tested in a high temperature environment. Several characteristics of this device make it ideal for detecting producing fractures. Whereas commercial induction logging devices have source receiver separations of 1 m, this device has multiple sensors with separations up to 8 m, allowing for deeper penetration and the ability to straddle fracture-induced washout zones in boreholes. The three-component measurements also make it possible to map the strike and inclination of nearby fractures and other three-dimensional structures. This, in turn, allows for accurate projection of these structures into the space between wells.��In this paper, we describe the design of the tool and show results of a performance test carried out in an oil-field steam flood. Data from vertical sensors are compared to conventional logging results and indicate�the recent formation of a low-resistivity zone associated with high temperatures due to steam flood breakthrough. Horizontal field data indicate that the hgh-temperature zone is irregular in the vicinity of the borehole and more pronounced closest to the steam injector.� |