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Using Advanced Formation Evaluation and Well Placement Techniques in Horizontal Wells to Improve Reservoir Delineation and Avoid Problem Areas*
Jason L. Pitcher1, D. Hoyt2, Jean Henderson2 and M. Bittar3
Search and Discovery Article #40459 (2009)
Posted October 15, 2009
* Adapted from expanded abstract presented at AAPG Annual Convention and Exhibition, Denver, Colorado, USA, June 7-10, 2009.
1Sperry Drilling Services, Halliburton Energy Services, Anchorage, AK ([email protected])
2Warren Resources, Long Beach, CA
3Halliburton Energy Services, Houston, TX
This paper discusses the use of a newly deployed azimuthal deep
resistivity sensor for advanced geosteering and well placement while drilling
in the Wilmington field. The advanced geosteering capabilities of this sensor,
in conjunction with integrated geosteering software, enabled the asset team to
design an optimum well 
trajectory
to isolate a previously produced well that
exhibited water coning and to place the well in an optimum position to maximize
production. The well was steered using the azimuthal deep sensor, and bed
boundaries were identified and mapped. The mapping information, from the sensor
at some distance from the boundary, was incorporated into the structure map,
enabling the asset team to refine the structure in this part of the reservoir
and to confirm/discount previous structural interpretations. This system, with
multiple depths of investigation and an azimuthal 32-bin measurement around the
borehole, created a complete picture around the sensor. This complete picture
improved our understanding of the reservoir’s structure and aided us in the
precise well placement required for isolation and proper reservoir drainage.
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Horizontal wells are not usually used in the industry to update reservoir structure maps, which results in maps that are missing crucial information about the geometry of the reservoir. Consequently, wells are being planned and drilled with increased uncertainty. Unexpected exits and drilling through water contacts are increasing costs. These unexpected events can be mitigated if appropriate sensor technology and appropriate data is acquired and used during the horizontal drilling of wells. In highly produced clastic reservoirs, such as the Wilmington field (Figure 1), well control forms the backbone of structure mapping. Conventional interpretation uses the abundant vertical wells data in the field to develop a structure map. The asset team uses the structure map to identify and plan horizontal wells to access unproduced pockets of hydrocarbons (Figure 2).
Well #1 of the WTU 2369 horizontal section was planned to place
the
After drilling the casing shoe and entering the reservoir, drilling proceeded as planned. The distance to bed inversion provided mapping of the top of the reservoir until 3,680 ft MD (Figure 4). At this point, an unexpected fluid change was encountered, causing the inversion to collapse. The resistivity in the zone had changed from 40 ohm-m to 6 ohm-m. This change was unexpected from the pre-drill model, and it was apparent that water had displaced the oil in this area.
Revisiting the structure map and reviewing old records of the
area showed that an old well that had produced considerable water caused
coning in the immediate area around the
Immediate remedial action was required. The drilling BHA was
tripped and a cement plug was set up into the casing. A revised plan was
developed where the new sidetrack was to drill to the north of the original
plan, and to intersect the top shale cap of the reservoir. This must be
placed precisely to enable the well to crest in the shale before reentering
the reservoir, minimizing the lost production section while isolating the
water cone from the
Drilling resumed from the casing shoe, with the well being deviated to the north and away from the original hole. The distance to bed inversion algorithm began to pick up the upper boundary of the reservoir at 3,400 ft MD and indicated the boundary position at 20 ft above the well (Figure 6).
This was at the maximum range of the tool and the subsequent inversion was “noisy,” but we mapped the boundaries and found that they compared very well with the revised structural map.
The well was drilled up with a desired exit from the reservoir at 3,700 ft MD (2,660 ft true vertical depth (TVD)). The boundary was mapped and the exit was made at the correct point. The boundary was continually mapped below the tool so that the exit point could be refined, which was done at 2,875 ft MD (2,667 ft TVD).
From the reentry point to the end of the well at 5,905 ft MD, the upper boundary was in almost constant range of the tool. At one point, at 4,850 ft MD, the structural variation took the boundary out of range of the tool. This defined the range of boundary detection of the InSite ADR™ tool in this reservoir to be 22 ft in radius. The boundary was mapped shortly afterward, at 5,010 ft MD, and mapped successfully to TD.
By using the best of existing new technology, well placement has undergone a revolution in its capability to deliver results. This example illustrates real-time mapping of boundaries and the flood zones, in which zonal isolation was accomplished without compromising well design or incurring additional completion costs. The ability of a well-trained and capable team, given the most appropriate tools for the job, to perform real-time well plan modifications to the extent shown here demonstrates how efficient and cost effective such systems can be in the right application.
Bittar, M., J. Klein, R. Beste, G. Hu, M. Wu, J. Pitcher, C. Golla, G. Althoff, V. Sitka, V. Minosyan, and P. Paulk, 2007, A new Azimuthal deep-reading resistivity tool for Geosteering and advanced formation evaluation: SPE Annual Technical Conference and Exhibition, 11-14 November 2007, Anaheim, California, Paper SPE 109971. Web accessed 22 September 2009 http://www.onepetro.org/mslib/servlet/onepetropreview?id=SPE-109971-PA&soc=SPE
The authors would like to thank the management of Warren E&P and Halliburton Energy Services for permission to publish this work.
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