Applying time-lapse seismic methods to reservoir management and field development planning at South Arne, Danish North Sea
Applying time-lapse seismic methods to reservoir management and field development planning at South Arne, Danish North Sea (in Petroleum geology; from mature basins to new frontiers; proceedings of the 7th petroleum geology conference, B. A. Vining (editor) and S. C. Pickering (editor))
Petroleum Geology Conference Series (2010) 7: 523-535
- Atlantic Ocean
- AVO methods
- basin inversion
- carbonate rocks
- chalk
- Cretaceous
- Denmark
- development
- Ekofisk Field
- Europe
- geophysical methods
- mathematical models
- Mesozoic
- monitoring
- natural gas
- North Atlantic
- North Sea
- oil and gas fields
- petroleum
- petroleum engineering
- planning
- reservoir rocks
- Scandinavia
- sedimentary rocks
- seismic methods
- time-lapse methods
- Tor Formation
- Upper Cretaceous
- Western Europe
- South Arne Field
At South Arne a highly repeatable time-lapse seismic survey (normalized root-mean-square error or NRMS of less than 0.1) allowed us to reliably monitor reservoir production processes during five years of reservoir depletion. Time-lapse AVO (amplitude v, offset) inversion and rock physics analysis enables accurate monitoring of fluid pathways. On the crest of the field, water injection results in a heterogeneous sweep of the reservoir, whereby the majority of the injected water intrudes into a highly porous body. This is in contrast to a pre-existing reservoir simulation model predicting a homogeneous sweep. On the SW dank, time-lapse AVO inversion to changes in water saturation ASW reveals that the drainage pattern is fault controled. Time-lapse seismic data furthermore explain the lack of production from the far end of a horizontal producer (as observed by production logging), by showing that the injected water does not result in the expected pressure support. On the highly porous crest of the reservoir compaction occurs. Time-lapse time shifts in the overburden are used as a measure for compaction and are compared with predictions of reservoir compaction from reservoir geomechanical modelling. In areas where compaction observations and predictions disagree, time-lapse seismic data give the necessary insight to validate, calibrate and update the reservoir geomechanical model. The information contained in time-lapse seismic data can only be fully extracted and used when the reservoir simulation model, the reservoir geomechanical model and the time-lapse seismic inversion models are co-visualized and available in the same software application with one set of coordinates. This allows for easy and reliable investigation of reservoir depletion and gives deeper insight than using reservoir simulation or time-lapse seismic individually.