Deep Offshore Fields Research Articles

Intelligent Production Prediction of Deep Offshore Hydrocarbon Reservoir: A Case Study of Niger-Delta Region of Nigeria

Current methods for predicting output, such as material balancing and numerical simulation, need years of production history, and the model parameters employed determine how accurate they are. The use of artificial neural network (ANN) technology in the production forecasting of a deep offshore field under water injection/water flooding in Nigeria’s Niger-Delta region is investigated in this study. Oil, water, and gas production rates were predicted using well models and engineering features. Real-world field data from producer and water injection wells in deep offshore is used to test the models’ performance. Ninety percent (90%) of the historical data were utilised for training and validating the model framework before being put to the test with the remaining information. The predictive model takes little data and computation and is capable of estimating fluid production rate with a coefficient of prediction of more than 90%, with simulated results that match real-world data. The discoveries of this work could assist oil and gas businesses in forecasting production rates, determining a well’s estimated ultimate recovery (EUR), and making informed financial and operational decisions.

A New Progressive and Efficient Royalty Model for Upstream Petroleum Industry

In this research paper, a new methodology to design a progressive and win-win royalty model for upstream fiscal systems is developed. The proposed royalty model is designed as a function of different boundary conditions of the market and the productive resources. These boundary conditions include the associated exploration and production risks, commodity prices, the extraction costs, besides the expected production and depletion rate. The behavior of the proposed royalty model under different oil prices, development costs, production rates, and exploration risks is investigated using deterministic and stochastic analysis. Our results prove that the applicable royalty rate increases with both the price and production rate while it decreases with increasing the development costs and the associated exploration and production risks. In addition, the proposed royalty model provides the contractor with sufficient incentives to develop marginal or low profitability fields and the development of deep offshore or frontier fields with high development and operating costs.

Forecast of Gas Production from Deep Offshore Field Using Exponential Decline Curve Analysis Technique – A Case Study of a Typical Niger Delta Field

The Niger Delta region of Nigeria has been a focal point in Nigeria’s Oil and gas Industry, being the epicenter of oil and gas activities and thus a has drawn a lot of scholarly attention in the quest to gain more insight into the wealth of the resources underneath. This work uses data from existing gas deep offshore production field to forecast the gas production using the decline curve technique. The result shows an annual gas production of 146BCF and a steady decline rate of 0.15BCF/Year and a total of 1.151 TCF of gas throughout the life of the field. Key Words: Forecast, Offshore, Natural gas, Production rate, Gas field.

Discriminating Between Second-Order Model With/Without Interaction Base on Central Tendency Estimation

The study deals with discriminating between the second-order models with/without interaction on central tendency estimation using the ordinary least square (OLS) method for the estimation of the model parameters. The paper considered two different sets of data (small and large) sample size. The small sample size used data of unemployment rate as a response, inflation rate and exchange rate as the predictors from 2007 to 2018 and the large sample size was data of flow-rate on hydrate formation for Niger Delta deep offshore field. The〖 R〗^2, AIC, SBC, and SSE were computed for both data sets to test for adequacy of the models. The results show that all three models are similar for smaller data set while for large data set the second-order model centered on the median with/without interaction is the best base on the number of significant parameters. The model’s selection criterion values (R^2, AIC, SBC, and SSE) were found to be equal for models centered on median and mode for both large and small data sets. However, the model centered on median and mode with/without interaction were better than the model centered on the mean for large data sets. This study shows that the second-order regression model centered on median and mode are better than the model centered on the mean for large data set, while they are similar for smaller data set. Hence, the second-order regression model centered on median and mode with or without interaction are better than the second-order regression model centered on the mean.

Prediction of Fracture Pressure in Niger Delta Deep Offshore

During drilling operations, it is essential to keep the wellbore pressure within the maximum value of the fracture pressure and minimum value of the pore pressure of the formation. To handle this challenge, the fracture pressure of the formation must be known as it is significant to determining the mud window design. This study developed a correlation that could predict the formation fracture pressure in the Niger Delta deep offshore field. Two different fields were considered for this model named Field 1 and 2. From these fields, fracture pressure data were gotten from 21 wells during leak off test (LOT) at different casing shoe depths. While carrying-out the analysis of data, assumptions were made that the formations throughout the Niger Delta basin obeys the principle of horizontality. Also, that the fracture pressure at same depth is uniform with the pressure at other location in the Delta. Scatter plot was used as the tool for the data analysis. A line of best fit was drawn to arrive at the correlation. This correlation has an R2 coefficient values of 0.9969. In conclusion, the correlation gotten from this study for predicting fracture pressure has shown to align with some data sets from the Niger Delta fields with very little variation. This can be used for planning of further drilling operations in the Niger Delta to make it easier, faster and more economical.

Prediction of Fracture Pressure in Niger Delta Deep Offshore

During drilling operations, it is essential to keep the wellbore pressure within the maximum value of the fracture pressure and minimum value of the pore pressure of the formation. To handle this challenge, the fracture pressure of the formation must be known as it is significant to determining the mud window design. This study developed a correlation that could predict the formation fracture pressure in the Niger Delta deep offshore field. Two different fields were considered for this model named Field 1 and 2. From these fields, fracture pressure data were gotten from 21 wells during leak off test (LOT) at different casing shoe depths. While carrying-out the analysis of data, assumptions were made that the formations throughout the Niger Delta basin obeys the principle of horizontality. Also, that the fracture pressure at same depth is uniform with the pressure at other location in the Delta. Scatter plot was used as the tool for the data analysis. A line of best fit was drawn to arrive at the correlation. This correlation has an R2 coefficient values of 0.9969. In conclusion, the correlation gotten from this study for predicting fracture pressure has shown to align with some data sets from the Niger Delta fields with very little variation. This can be used for planning of further drilling operations in the Niger Delta to make it easier, faster and more economical.

Experimental investigation of pressure drop in failed Electrical Submersible Pump (ESP) under liquid single-phase and gas-liquid two-phase flow

The high viscosity of heavy oil calls for additional efforts to ensure the production in deep offshore fields, requiring innovative ways to optimize oil recovery. Considering the production by pumping system, one of the current approaches to increase the profitability is to associate the in-well Electrical Submersible Pump (ESP) and the Seabed Boosting ESP (SB-ESP). In this Tandem system, the oil must flow through the ESP while it is failed or damaged until it reaches the SB-ESP, resulting in additional head loss. This study aims to estimate the pressure drop in a damaged ESP under field conditions. For this, the study is divided into two parts. First, the pressure drop through the ESP is measured experimentally and empirical correlations are adjusted for the loss coefficient as a function of the flow parameters. Second, based on these empirical correlations and the use of black oil models for fluid properties, simulations are carried out to estimate the pressure drop under field conditions. The main contribution of this study is to provide experimental correlations for local pressure in a failed ESP since these are not available in the literature. The experimental tests used oil single-phase flow at different flow rates and viscosities. In addition, gas-liquid two-phase flow tests were performed to investigate the gas influence on the pressure drop. The experimental results indicate a decreasing dependence between loss coefficient and the Reynolds number. Regarding the fitted correlations, all equations correctly predicted the experimental data, with determination coefficients greater than 0.930. For gas-liquid two-phase flow results, the homogeneous model was suitable for predicting the pressure drop at the ESP within the experimental matrix, with gas fractions up to 35%.

Анализ петрофизических исследований глубокозалегающих нефтегазовых коллекторов сухопутных и морских месторождений Азербайджана

The paper presents results of generalized laboratory studies from an array of petrophysical parameters of reservoir rocks (potential hydrocarbon reservoirs). The study is targeted at well-known horizons of productive strata of the Meso- Cenozoic sedimentary basin. The area under study includes oil and gas onshore and deep offshore fields in Azerbaijan that have been under active continuous developments. The development of these natural hydrocarbon accumulations has over a century-long history, which has shown that the major oil and gas deposits are associated with the South Caspian and Kura depressions subjected to an intensive submersion over the Meso-Cenozoic period. Although many of the fields in these depressions have been exploited for a long time, the commercial potential is high enough, especially in deep-seated areas. Nonetheless, problems associated with extracting oil and gas therefrom are pending final resolutions. Subsoil developments in the region are currently performed at an intensive rate at depths above 4-4.5 km, since most oil and gas deposits have already been explored at shallow and moderate depths (even in hard-to-reach areas). As known in oil industry, the wells with a depth of over 4 km are referred to deep wells, while those with a depth of over 6 km are referred to ultra-deep wells. Moreover, drilling of such wells is associated with serious costrelated challenges. For example, the cost of developing deep and even ultra-deep wells is high enough, ranging from $ 2-3 to $ 9-12 million. This fact emphasizes the need to enhance efficiency of such operations, which requires a highscale geological reasoning of a field’s potential and choice of a good location.

A Numerical Study on the Optimal design of In-line Type Subsea Separator

Subsea separation is an attractive and economic solution to develop deep offshore fields producing fluid without hydrate or wax. The subsea separation system should be reliable to ensure successful operation in a wide range of multiphase flow regime, without need for developments. A subsea separator can avoid or simplifying costly surface platforms of floating vessels, as well as being an efficient tool to enhance hydrocarbon production. One solution of interest is the separation and re-injection of water at the seabed to avoid bringing the water up to the surface facility. In this study, multiphase flow characteristics inside in-line type subsea separation system are investigated for the design of subsea separation system. The separation efficiency of the subsea separator is determined through experiments that are the liquid-gas phased separation. Also internal swirl element (ISE) modelling of the separator was optimized. The analysis results were utilized to improve the reliability and efficiency of the subsea separation system.

Nonlinear dynamic and bilinear fatigue reliability analyses of marine risers in deep offshore fields

ABSTRACTDepleting oil reserves in shallow water are opening the avenues of new ventures in deep sea conditions. India is no exception; deep sea explorations are highly recommended and exercised. As part of the design process, there are requirements of structural failure criteria, such as rupture by over loading, fatigue failures, buckling or an unstable fracture. Three-dimensional nonlinear dynamic analysis of riser is obtained in time domain using finite-element solver ABAQUS/Aqua. The response histories so obtained are employed for the study of fatigue reliability assessment of risers. Fatigue model is based on a bilinear relationship that gives the crack growth linked failure criterion to describe the interaction between fracture and plastic collapse. Uncertainty modelling, especially fatigue crack growth parameters, is undertaken with the help of recently published data in support of bilinear crack growth relationship. Results pertaining to fatigue reliability and fatigue crack size evolution are presented using Monte Carlo simulation. The bilinear crack growth model is found to lead to higher fatigue life estimation as compared to linear fracture mechanics model. Sensitivity behaviour pertinent to limit state adopted has been thoroughly investigated. These findings implicate inspection schemes for components of the marine structures to ensure minimisation of the surprises due to wide scatter of the fatigue phenomenon in marine environment.

Polymer Injection in Deepwater Field Offshore Angola

This article, written by JPT Technology Editor Chris Carpenter, contains highlights of paper SPE 174699, “Dalia/Camelia Polymer Injection in Deep Offshore Field, Angola: Learnings and In-Situ Polymer-Sampling Results,” by D.C. Morel, E. Zaugg, S. Jouenne, J.A. Danquigny, and P.R. Cordelier, Total, prepared for the 2015 SPE Enhanced Oil Recovery Conference, Kuala Lumpur, 11–13 August. The paper has not been peer reviewed. The polymer-injection project in the Dalia field, one of the main fields of Block 17 in deepwater Angola, represents a world first for both surface and subsurface aspects. Thorough, integrated geoscience and architectural studies led to the decision to initiate a polymer-injectivity test on a single well, followed by a continuous injection of polymer on one of the four subsea lines delivering water to the field. The complete paper describes the main results of the pilot phase. Introduction A subsea development scheme with water injection for full pressure maintenance was chosen for the Dalia field together with gas reinjection. Very early in the geoscience studies, oil viscosity was identified as the main limiting factor to water-injection recovery. Polymer injection was positively screened as a potential enhanced-oil-recovery method for the field. Extensive feasibility studies of polymer flooding were initiated in 2003, 3 years before production start-up. A phased approach was chosen to assess and reduce the main uncertainties of the project, consisting of the construction of a powder-polymer solution-preparation skid, a single-well injectivity test, a longer injection period through one of the injection lines (supplying three wells), and the drilling of a sampler/producer well to assess in-situ viscosity, while continuing surface and subsurface studies. Dalia Reservoir The field is developed by water injection, using a floating production, storage, and offloading (FPSO) vessel with 28 deviated or horizontal subsea injector wells and four injection flowlines (plus three gas-reinjection wells active before Angolan liquefied-natural-gas startup). A single flowline generally injects into several reservoirs as well as several systems. Maximum yearly average water injection is 360,000 BWPD. Desulfated seawater has been injected since startup to prevent any barium sulfate deposition, and all the produced water is reinjected. Production is achieved through four production lines and 40 producers. First oil was on 13 December 2006. The 240,000-B/D oil-production plateau was reached after a few months, while, at the time of this writing, 8 years after startup, the field is still producing at a reduced plateau rate of 200,000 BOPD. A schematic of the layout is provided in Fig. 1.

Time-Lapse Seismic for Reservoir Management: Case Studies From Offshore Niger Delta, Nigeria

Summary This paper presents case studies focused on the interpretation and integration of seismic reservoir monitoring from several fields in conventional offshore and deepwater Niger Delta. The fields are characterized by different geological settings and development-maturity stages. We show different applications varying from qualitative to quantitative use of time-lapse (4D) seismic information. In the first case study, which is in shallow water, the field has specific reservoir-development challenges, simple geology, and is in phased development. On this field, 4D seismic, which was acquired several years ago, is characterized by poor seismic repeatability. Nevertheless, we show that because of improvements from seismic reprocessing, 4D seismic makes qualitative contributions to the ongoing field development. In the second case study, the field is characterized by complex geological settings. The 4D seismic is affected by overburden with strong lateral variations in velocity and steeply dipping structure (up to 40°). Prestack-depth-imaging (PSDM) 4D seismic is used in a more-qualitative manner to monitor gas injection, validate the geologic/reservoir models, optimize infill injector placement, and consequently, enhance field-development economics. The third case study presents a deep offshore field characterized by a complex depositional system for some reservoirs. In this example, good 4D-seismic repeatability (sum of source- and receiver-placement differences between surveys, dS+dR) is achieved, leading to an increased quantitative use of 4D monitoring for the assessment of sand/sand communication, mapping of oil/water (OWC) front, pressure evolution, and dynamic calibration of petro-elastic model (PEM), and also as a seismic-based production-logging tool. In addition, 4D seismic is used to update seismic interpretation, provide a better understanding of internal architecture of the reservoirs units, and, thereby, yield a more-robust reservoir model. The 4D seismic in this field is a key tool for field-development optimization and reservoir management. The last case study illustrates the need for seismic-feasibility studies to detect 4D responses related to production. In addition to assessing the impact of the field environment on the 4D- seismic signal, these studies also help in choosing the optimum seismic-survey type, design, and acquisition parameters. These studies would possibly lead to the adoption of new technologies such as broad-band streamer or nodes acquisition in the near future.

A Fully Coupled Network Model: Comparison With Other Integrated Models on Field Cases

This article, written by Special Publications Editor Adam Wilson, contains highlights of paper SPE 173251, “A Fully Coupled Network Model—Practical Issues and Comprehensive Comparison With Other Integrated Models on Field Cases,” by H. Cao, SPE, P. Samier, SPE, H.M. Kalunga, E. Detige, and E. Obi, SPE, Total, prepared for the 2015 SPE Reservoir Simulation Symposium, Houston, 23–25 February. The paper has not been peer reviewed. There has been increasing interest in integrated simulation of reservoirs, wells, and surface facilities, which is particularly important for companies with major assets in deep offshore fields. The basic approach for integration can be split into decoupled or separated (between a reservoir simulator and a facility simulator), iteratively coupled, and fully coupled networks, with increasing stability and efforts in implementation. This paper covers the development of a state-of-the- art fully coupled network inside a next-generation commercial reservoir simulator and compares different coupling approaches on real field cases. Introduction Two basic and diverse strategies exist for integrated simulation. The separated strategy focuses on loosely coupling separate software together, typically between an existing reservoir simulator and an existing facility simulator. The combined strategy focuses on tight integration within a single piece of software, typically a reservoir simulator that also models surface facilities. Both of these strategies have their advantages and disadvantages, and both are actively used in the industry. In the separated strategy, a reservoir simulator is used for reservoir and wells modeling and a facility simulator is used for surface-facility modeling. The information exchange [well inflow performance relationship (IPR) from reservoir to facility and well pressure/rate constraint] happens per timestep or periodically between the two simulators through a custom-made controller. The main advantages of this strategy are its low cost in development (mostly associated with the controller) and its flexibility in allowing users to use the reservoir and surface simulators that fit their needs best. On the other hand, as a loosely coupled (here referred to as decoupled) method, it often suffers from numerical instability because the IPR calculated at the beginning of the coupling timestep is not representative of the IPR at the end of the coupling timestep, which is particularly true for the kind of fine and full-featured reservoir models used in reservoir-simulation studies, where well-perforation cells are much smaller than the well-drainage radius. There are also other issues for the strategy. For instance, the information exchanged is based on IPR of individual (and independent) wells without proper accounting of well interference anywhere in the coupling scheme and in the IPR generation and format. However, well interference can become important when opening and shutting nearby wells and when modeling smart wells with well laterals and segments controlled individually. The separated strategy typically requires a combination of software across multiple platforms. In the combined strategy, a reservoir simulator typically is extended to model the facility, thus everything is contained within a single simulator. Contrary to the facility model in a standalone advanced facility simulator, the facility model in a reservoir simulator is a more simplified one in both topology and modeling. The iteratively coupled methods can differ further according to the frequency of coupling and the definition of timestep convergence. Recently, recognizing the fact that both wells and surface facilities model flow in pipes, researchers started to examine the idea of using a general pipe-network module to model both. This network module can replace the traditional well module inside a reservoir simulator in all aspects and, hence, achieve fully implicit coupling among reservoir, wells, and surface facilities. The combined strategy takes considerably more time and effort to develop, but, in turn, it ensures much-improved stability and speed, yielding generous payouts well worth the initial investment. Because of its ease of use (using only a single piece of software) and much-improved stability and speed, especially for fine and detailed reservoir models, this combined strategy has been recommended to and is often preferred by reservoir engineers for reservoir studies of deep offshore fields. The fully implicitly coupled network is the most advanced next-generation approach available. It is unconditionally stable and offers the best speed and performance possible. This approach has been featured in most next-generation industrial reservoir simulators.

Polymer Injection in a Deep Offshore Field - Angola, Dalia/Camelia Field Case

This article, written by Senior Technology Editor Dennis Denney, contains highlights of paper SPE 135735, ’First Polymer Injection in a Deep Offshore Field - Angola: Recent Advances on Dalia/ Camelia Field Case,’ by Danielle Morel, SPE, and Michel Vert, Total E&P; Stephane Jouenne, SPE, Total Petrochemicals; and Renaud Gauchet and Yann Bouger, Total E&P Angola, prepared for the 2010 SPE Annual Technical Conference and Exhibition, Florence, Italy, 19-22 September. The paper has not been peer reviewed. Key challenges of the polymer-injection project in the Dalia field, offshore Angola, were to start polymer injection: Very early in the field development With much wider well spacing than in other projects Under high-salinity conditions (>25g/L) With specific logistics of a remote deep offshore area Introduction The Dalia field is 130 km offshore Angola, with an estimated 1 billion bbl of recoverable oil. Water depth varies between 1200 and 1400 m, with reservoirs 800 to 1000 m below the seabed. Very-high-quality 3D-seismic data enabled mapping of the main reservoir structure, including sands and clay areas only 6 to 10 m thick. The channel complexes can be as thick as 100 m but are divided into heterogeneous sections with alternating layers of oil sands and clays. Permeability ranges from a few hundred millidarcies to several darcies, with an average permeability greater than 1 darcy. The reservoir temperature ranges from 45 to 56°C, and reservoir pressure is 215 to 235 bar. The 19 to 38°API oil is slightly undersaturated, with viscosity ranging from 1 to 11 cp at reservoir conditions. Water viscosity is approximately 0.5 cp at reservoir conditions. The field produces by energy from water injection, using a floating production, storage, and offloading (FPSO) vessel with 31 deviated or horizontal subsea injector wells and four injection flowlines. Generally, a single flowline is used to inject into several reservoirs and several systems. Maximum water injection is 405,000 BWPD. Production is achieved through four production lines and 37 producers. First oil was on 13 December 2006. The 240,000-BOPD plateau rate was reached after a few months and has been maintained since. Seawater is desulfated to prevent risk of barium sulfate deposit, and has been injected from the start. Produced water will be reinjected after water breakthrough. By June 2010, 25 producer wells were connected and water breakthrough had occurred in several wells, with water cut ranging from a few percent to more than 40%. The current water-injection salinity is approximately 50 g/L.

Flow Assurance Issues and Control with Naphthenic Oils

Naphthenic oil production is known to be made difficult by stable emulsion formation and possible scaling of calcium naphthenates. From a flow assurance point of view, it is of major importance to foresee these two possible issues at the earliest stage of the project development especially for deep-offshore fields. In this article, a classification of crude oils based on density, acidity and acid types is proposed. Process schemes adapted to the different oil types are also described.

Influence of Viscosity on ESP Performance

This article, written by Technology Editor Dennis Denney, contains highlights of paper SPE 110661, "On the Influence of Viscosity on ESP Performance," by Gilmar Amaral and Valdir Estevam, Petroleo Brasileiro S.A, and Fernando A. Franca, SPE, State University of Campinas, prepared for the 2007 SPE Annual Technical Conference and Exhibition, Anaheim, California, 11–14 November. The paper has not been peer reviewed. Experimental data and a preliminary analysis of the operation of centrifugal pumps with viscous liquids are presented. Two centrifugal pumps, a conventional radial and a semiaxial electrical submersible pump (ESP), were instrumented and tested with water and clear glycerin. The glycerin viscosity was varied from 67 to 1,020 cp by changing the temperature, encompassing the viscosity range of light-to-heavy oils. The main purpose of these tests, besides measuring the influence of viscosity on the pump overall performance, was to supply detailed information on the energy-transfer processes taking place in the pumps' internal components. Introduction ESPs have been used increasingly as an artificial-lift method to produce medium-to-heavy oils in deep offshore fields. The pump may be inside the well or, depending on technical requirements, above the seabed to reduce intervention costs, as is the case in Jubarte field in Campos basin, Brazil. When the oil viscosity is too high to allow efficient pump operation, the oil viscosity can be reduced by injecting light oil (usually referred to as a downgrading technique) or solvents upstream of the pump suction or by raising the mixture temperature. When installed on the seabed, series- or parallel-arranged pump systems can be used to reduce the power required by each pump. Thus, new operation strategies and different equipment allocation and arrangements have been used to exploit heavy oils in these harsh environments. In Jubarte field, an ESP was installed in the production riser, just above the tree, to lift the raw mixture to the platform. When the ESP is on the seabed, the fluid temperature may be lower than the reservoir temperature. The heat generated in the ESP, which reduces the fluid viscosity and increases pump performance, is partially lost to the surrounding cold water. As the pumped mixture cools and attains a higher viscosity, pump performance is affected. Additionally, a pump at seabed level operates at a reduced inlet pressure compared with an in-well pump and may increase the free-gas content, additionally reducing pump performance. Therefore, fluid viscosity is a key technical issue when selecting an ESP to lift medium-to-heavy oil in offshore fields. The performance of pumps operating with liquids of various viscosities is obtained by either empirical or deterministic methods. Empirical methods usually try to adjust the pump performance starting with the published pump-characteristic curves for water. Nondimensional parameters and correcting coefficients for hydrostatic head and efficiency for a given flow rate and fluid viscosity are used to estimate the actual characteristics on the basis of those for water. However, the database is limited in terms of pump characteristics and operational conditions.