Abstract
Produced Water Chemistry data (PWC) is the main source of information to monitor scale precipitation in oil field operations. Chloride concentration is used in order to evaluate the seawater fraction of the total produced water per producing well and is included as an extra history matching constraint to revaluate a good conventionally history matched reservoir model for the Janice field. Generally PWC is not included in conventional history matching and this approach shows the value of considering the nature of the seawater injection front and the associated brine mixing between the distinctive formation water and injected seawater.
Adding the extra constraint resulted in the re-conceptualization of the reservoir geology between a key injector and two producers. The transmissibility of a shale layer is locally modified within a range of geologically consistent values. Also, a major lineament is identified which is interpreted as a NW-SE trending fault, whereby the zero transmissibility of a secondary shale in the Middle Fulmar is locally adjusted to allow cross-flow. Both uncertainties are consistent with the complex faulting known to exist in the region of the targeted wells. Other uncertainties that were carried forward to the assisted history matching phase included: water allocation to the major seawater injectors; thermal fracture orientation of injectors and the vertical and horizontal permeability ratio (kv/kh) of the Fulmar formation.
Finally, a Stochastic Particle Swarm Optimization (PSO) algorithm is used to generate an ensemble of history matched (HM) models using seawater fraction as an extra constraint in the misfit definition. Use of addition data in history matching has improved the original good history matched solution. Field Oil Production Rate is interpreted as improved over a key period and although no obvious improvement was observed in Field Water Production Rate, Seawater fraction in a number of wells was improved.
Adding the extra constraint resulted in the re-conceptualization of the reservoir geology between a key injector and two producers. The transmissibility of a shale layer is locally modified within a range of geologically consistent values. Also, a major lineament is identified which is interpreted as a NW-SE trending fault, whereby the zero transmissibility of a secondary shale in the Middle Fulmar is locally adjusted to allow cross-flow. Both uncertainties are consistent with the complex faulting known to exist in the region of the targeted wells. Other uncertainties that were carried forward to the assisted history matching phase included: water allocation to the major seawater injectors; thermal fracture orientation of injectors and the vertical and horizontal permeability ratio (kv/kh) of the Fulmar formation.
Finally, a Stochastic Particle Swarm Optimization (PSO) algorithm is used to generate an ensemble of history matched (HM) models using seawater fraction as an extra constraint in the misfit definition. Use of addition data in history matching has improved the original good history matched solution. Field Oil Production Rate is interpreted as improved over a key period and although no obvious improvement was observed in Field Water Production Rate, Seawater fraction in a number of wells was improved.
Original language | English |
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Title of host publication | 75th European Association of Geoscientists and Engineers Conference and Exhibition 2013 |
Subtitle of host publication | Changing Frontiers: Incorporating SPE EUROPEC 2013 |
Place of Publication | Houten |
Publisher | EAGE Publishing BV |
Pages | 2920-2934 |
Number of pages | 15 |
ISBN (Electronic) | 9781613992548 |
ISBN (Print) | 9781629937915 |
DOIs | |
Publication status | Published - 2013 |
Event | 75th EAGE Conference and Exhibition 2013 - London, United Kingdom Duration: 10 Jun 2013 → 13 Jun 2013 |
Conference
Conference | 75th EAGE Conference and Exhibition 2013 |
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Abbreviated title | SPE EUROPEC 2013 |
Country/Territory | United Kingdom |
City | London |
Period | 10/06/13 → 13/06/13 |