ABSTRACT: Improving Recovery from the Dunlin Field, U.K. Northern North Sea

C. I. M. Braithwaite, J. D. Marshall, T. C. Holland

The Dunlin field lies 160 km northeast of the Shetland Islands at the western edge of the Viking graben. Located in 150 m of water, it extends from Shell/Esso's license Block 211/23a into Conoco/Chevron/Britoil's 211/24a acreage. The oil accumulation is trapped by a heavily faulted horst block within the Middle Jurassic Brent Group sequence. The field was discovered in 1973 and development drilling began in 1977.

Despite poor definition of the reservoir configuration, a two-dimensional seismic survey shot in 1974 was used for field development planning. The advent of three-dimensional seismic helped address this limitation and a survey covering the entire field was acquired in 1977-79. The top Brent could then be mapped across the whole field and major faults properly defined resulting in immediate changes to planned development well locations. As drilling progressed, well results in the complex eastern flank indicated the need for improved resolution of fault positions, and in 1983, the survey was reprocessed to enhance definition of the flank area. The survey itself, however, was limited by the early three-dimensional technology, and a new three-dimensional survey was acquired in 1988 to all w optimum siting of the remaining wells and sidetracks required for field management.

Extensive shales divide the deltaic Brent Group sands into separate producing intervals. By July 1989, 33% of the 825 MMstb (131 × 106 stock-tank m³) STOIIP has been produced, principally from the high-permeability Tarbert and the channel-barrier sands of the Ness and Etive formations. A geological review is currently underway in parallel with the seismic interpretation in an effort to improve recovery from these sands. The bulk of the remaining oil, however, is located in the low permeability Rannoch Formation, directly underlying and in good pressure communication with the flooded Etive. An integrated petroleum engineering study was done to determine the viability of dedicated development.

The Rannoch is a coarsening-upward shoreface sequence of mica-rich sands. It is characterized by low-angle cross-bedding that is interpreted as hummocky cross-stratification (HCS). The formation is thickest in the southwest of the field. To support single-well simulations aimed at evaluating Rannoch recovery techniques a model of permeability distribution in HCS sands was developed from core and log data, which included the effects of impermeable concretions that occur sporadically.

Single-well simulation studies were done focusing on wells within the defined target area. The historical imbibition of water by gravity drainage from the flushed Etive into the Rannoch was matched, together with historical production behavior. The calibrated models predicted that Rannoch recovery could be increased by dedicated producers and, with optimal well spacing, incremental recoveries of between 1.5 and 2.0 MMstb (0.2 and 0.3 × 106 stock-tank m³) per well would be achieved with a relatively slow build-up of watercut.

Encouraged by these results, a development program was initiated in mid-1988. Recent well results from this campaign have so far been favorable. Oil production rates of more than 3000 stb/day (477 m³/day) are being experienced and watercuts are as expected. A horizontal well is being considered and the scope for additional activity will be evaluated following review of the results of the current campaign.

AAPG Search and Discovery Article #91003©1990 AAPG Annual Convention, San Francisco, California, June 3-6, 1990