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Predicting multiphase flow behavior in a deviated well

Journal Article · · SPE (Society of Petroleum Engineers) Product. Eng.; (United States)
DOI:https://doi.org/10.2118/15449-PA· OSTI ID:6468367
 [1];  [2]
  1. Univ. of North Dakota (US)
  2. Schlumberger Well Services (US)
+ Show Author Affiliations

In deviated wells of an offshore producing environment, flow of two- or three-phase mixtures is invariably encountered. While many investigators have studied vertical multiphase flow behavior, few studies, often entirely empirical, deal with deviated well systems. The main objective of this work is to present a model that predicts both flow regime and pressure gradient in a deviated wellbore. In the modeling of flow-pattern transition and void fraction, an approach similar to that for vertical flow is taken; i.e., four principal flow regimes are recognized: bubbly, slug, churn, and annular. The transition form bubbly to slug flow is found to be at a local void fraction of 0.25. This transition criterion in terms of gas and liquid superficial velocities is found to be significantly affected by the well deviation, particularly in highly deviated wells. The transitions from slug to churn flow and churn to annular flow occur at high fluid velocities and are unaffected by well deviation. The velocity-profile-distribution parameter for bubbly, slug, and churn flows is found to be unaffected by the well deviation angle. Similarly, the terminal rise velocity for small bubbles also appears to be insignificantly affected by the well deviation. In contrast, the ''Taylor'' bubble-rise velocity changes dramatically as deviation angle is increased. Thus, the characters of slug and churn flows in a deviated well differ from those in a vertical well. Data on gas void fraction were obtained both from a 5-in. (127-mm) circular pipe and from annular flow channels for deviation angles up to 32/sup 0/ from the vertical. The validity of the proposed model is demonstrated with these data and with laboratory data from other sources. Several field examples are presented to show the application of the model.

OSTI ID:
6468367
Journal Information:
SPE (Society of Petroleum Engineers) Product. Eng.; (United States), Journal Name: SPE (Society of Petroleum Engineers) Product. Eng.; (United States) Vol. 3:4; ISSN SPENE
Country of Publication:
United States
Language:
English

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Related Subjects

02 PETROLEUM
020300* -- Petroleum-- Drilling & Production
03 NATURAL GAS
030300 -- Natural Gas-- Drilling
Production
& Processing
42 ENGINEERING
423000 -- Engineering-- Marine Engineering-- (1980-)
DRILLING
EXPLORATORY WELLS
FIELD TESTS
FLUID FLOW
GEOLOGIC STRATA
GEOLOGIC STRUCTURES
INCLINED STRATA
MULTIPHASE FLOW
NATURAL GAS WELLS
OFFSHORE DRILLING
OIL WELLS
PRESSURE GRADIENTS
SCALE MODELS
STRUCTURAL MODELS
TESTING
VELOCITY
VERTICAL INTEGRATION
WELLS