Resolving a Water Shortcut Between Old Wells with Multiple Completion Zones: Example in the Dan Field

Eriksen, Katrine; Hansen, Ove Egstrøm; Post, N. van der

doi:10.2118/134423-ms

Cited by 2 publications

(1 citation statement)

References 15 publications

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“…The chalk of the Ekofisk Formation is richer in silica and clay and can be subdivided into an upper porous unit and a lower tighter, silica‐rich unit. The low matrix permeability of the chalk and few natural fractures necessitates production to be enhanced by artificial fracturing, the use of horizontal wells and water injection (Jørgensen, 1992; Eriksen et al ., 2010).…”

Section: Geological Settingmentioning

confidence: 99%

Relation of acoustic impedance to stiffness and porosity of Maastrichtian chalk in Dan field, Danish North Sea

Meireles

Welch

Fabricius

2022

Geophysical Prospecting

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In seismic data analysis, acoustic impedance may be used for predicting the porosity of a sedimentary layer with known lithology, where the influence on impedance from pore fluid is known. This method typically assumes that the stiffness of the rock frame is solely a function of porosity and that there is no variation in stiffness between rocks with the same composition and porosity. However, contact cementation can cause an increase in rock frame stiffness with no significant reduction in porosity. This means that rocks with similar porosities and varying degrees of cementation would have significantly different elastic moduli; thus, attempting to derive porosity from seismic impedance alone would incur errors. The primary goal of this study is to assess how significant this error is for porosity prediction. The secondary goal is to calculate the dry rock frame stiffness across the field and evaluate to what extent the time of hydrocarbon placement affects the lithification of the rock. To fulfill these objectives, we studied petrophysical logs and core data from the Dan field and derived seismic impedance, porosity and stiffness expressed in terms of Biot's coefficient for 14 wells across the field. Trends defined between acoustic impedance, porosity, and Biot's coefficient in the Maastrichtian unit of the Dan field showed that, for a given porosity and water saturation in the oil zone, the chalk located at the crest of the reservoir is softer than the chalk located at the flanks of the field. We also found that chalk is stiffer in the down-faulted north-western part of the field for a given porosity and water saturation in the oil zone. In the water zone, no difference was found. We speculate that contact cementation downflank in the northwest block caused an increase in the chalk stiffness without reducing the porosity, while earlier hydrocarbon filling of the south-eastern block and the crest of the structure delayed contact cementation between the chalk particles. This difference in contact cementation between rocks of the same porosity causes porosity prediction from acoustic impedance to vary by up to six porosity units.

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Section: Geological Settingmentioning

confidence: 99%

Relation of acoustic impedance to stiffness and porosity of Maastrichtian chalk in Dan field, Danish North Sea

Meireles

Welch

Fabricius

2022

Geophysical Prospecting

View full text Add to dashboard Cite

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Enhanced Oil Recovery Methods

Romero‐Zerón

2016

Exploration and Production of Petroleum and Natural Gas

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Oil and natural gas remain the dominant components of the worldwide energy system. The International Energy Agency (IEA) predicts that global energy demand will increase by at least 30 % over the next 20 years. It is expected that 99.7 million barrels per day will be needed in 2035. Therefore, the world economy depends on the availability of oil and natural gas resources, advances in oil production technologies, the development of alternative energy sources, and the existence of reliable energy supply routes. At present, the average worldwide oil recovery factor after primary and secondary oil recovery is in the order of one third of the total original-oil-in-place depending on the reservoir characteristics; hence, significant amounts of oil are left in the formation. To achieve oil recovery factors higher than 30 % from mature reservoirs, it is necessary to implement enhanced oil recovery (EOR) processes. Consequently, EOR methods will become increasingly important in the future. This chapter presents a brief description of the most common EOR processes as well as information on recent developments and field applications.

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Resolving a Water Shortcut Between Old Wells with Multiple Completion Zones: Example in the Dan Field

Cited by 2 publications

References 15 publications

Relation of acoustic impedance to stiffness and porosity of Maastrichtian chalk in Dan field, Danish North Sea

Relation of acoustic impedance to stiffness and porosity of Maastrichtian chalk in Dan field, Danish North Sea

Enhanced Oil Recovery Methods

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