Acoustic Emissions as a Tool for Hydraulic Fracture Location: Experience at the Fenton Hill Hot Dry Rock Site

1982 ◽  
Vol 22 (04) ◽  
pp. 523-530 ◽  
Author(s):  
James N. Albright ◽  
Christopher F. Pearson
Keyword(s):  
Water Injection ◽  
Acoustic Emissions ◽  
Reservoir Rock ◽  
Time Interval ◽  
Reservoir Pressure ◽  
Simulation Studies ◽  
Total Recovery ◽  
Tank Farm ◽  
Niger River ◽  
Original Oil In Place

Summary The Delta South field is situated on an anticlinal high, positioned between two major growth faults. The field is in an offshore environment in the Niger Delta area. The G-2 and G-3 reservoirs contain about 90% of the field's reserves. Primary production from these reservoirs is by gravity drainage and gas-cap expansion. The effect of water influx on the total recovery mechanism has been minimal. Reservoir engineering studies indicate primary depletion will permit the recovery of 30% of the original oil in place (OOIP). The installation of a waterflood pressure maintenance project should allow the ultimate recovery to be increased to approximately 50% of OOIP. Introduction The Delta South field was discovered in May 1965 and is situated approximately 3 miles offshore the coastline of Bendel State, Nigeria (Fig. 1). The field is in a complex of 10 offshore fields operated by Gulf Oil Co. (Nigeria) Ltd. (GOCON) in conjunction with the Nigerian Natl. Petroleum Co. (NNPC), which is the majority partner. Fig. 1 shows that the field is adjacent to the GOCON/NNPC Escravos River Tank Farm. The field is in a nearshore surf area, and the water depth varies from 10 to 16 A. Production from the field is derived principally from the G-2 and G-3 sands. The G-2 reservoir is at an average depth of 8,920 ft subsea and is underlain by the G-3 reservoir. The two sands are separated by an intervening 100-ft-thick shale member that excludes pressure and fluid communication. The two reservoirs are similar in structure and rock and fluid properties. The Delta South field commenced production in March 1968. The production of 21 % of OOIP from G-2 by March 1978 had resulted in a reservoir pressure decline of 33%. The production of 29% of OOIP from G-3 during this same time interval resulted in a reservoir pressure decline of 39%. Reservoir rock and fluid property data acquisition commenced in 1967 when Delta South Well 8 was cored with a rubber sleeve core barrel. In 1972 Delta South Well 13 was cored. Reservoir oil fluid sampling was done in 1968 and again in 1979. The initial sampling was a prelude to simulation studies carried out at the Gulf Research and Development Co. facilities in 1970. The results of these and subsequent simulation studies are presented in a separate paper (Part 2). The studies have indicated the need for the installation of a water injection project in the field. The necessary approvals have been obtained, and project start-up was scheduled for late 1981. This paper describes the Delta South field, the producing history, the expected results, the injection/producing method, and the facilities to be installed. Part 2 describes the reservoir simulation work and the results of those investigations. Field Description The Delta South G-2 and G-3 sands were deposited dun ing mid-Miocene time. These sands are part of an extensive barrier bar system related to the ancient Niger River. Since Eocene time, the depositional forces prevalent at the confluence of the Niger River and the Bight of Benin were dominated by waves and tides. These types of deltaic deposits often produce reservoir rock of excellent quality. First, wave and tidal current velocities are relatively constant, which results in a fairly uniform grain-size distribution. Second, the constant reworking of the sediments tends to remove clay particles. Third, the sand bodies tend to have a sheet on blanket geometry (sands can be correlated easily for at least 4 miles along strike and 2 miles along the dip). JPT P. 141^

An Independent Analysis of the Performance Characteristics and Economic Outcomes of the Liza Phase 1 Development Offshore Guyana Using Public Domain Data

2021 ◽  
Author(s):  
Simon Paul ◽  
Kadija Dyall ◽  
Quinn Gabriel
Keyword(s):  
Oil Recovery ◽  
Dynamic Models ◽  
Computer Modelling ◽  
Phase 1 ◽  
Water Injection ◽  
Public Domain ◽  
Gas Production ◽  
Google Earth ◽  
Reservoir Rock ◽  
Original Oil In Place

Abstract An attempt was made to independently verify the proposed performance of the Liza 1 field using only data available in the public domain. The data used in modelling was sourced from news reports, company disclosures and the analogue Jubilee field in Ghana. Reservoir rock and fluid data from Jubilee Field was deemed an appropriate fit because of the corroboration provided by the Atlantic Drift Theory. A major challenge in creating the model, was determining the aerial extent of the field. According to Yang and Escalona (2011), the subsurface can be reasonably approximated using the surface topography which is possible via the use of GIS software. Google Earth Pro software was used to estimate the coordinates and areal extent of the Liza 1 reservoir. A scaled image of the field location showing the Guyana coastline was re-sized to fit the coastline in Google Pro and then the coordinates for the Liza field and wildcat well locations were estimated. This was used to create the isopach map and set reservoir boundaries to create the static and dynamic models in Schlumberger's Petrel E & P Software Platform (2017) and Computer Modelling Group IMEX Black Oil and Unconventional Simulator CMG IMEX (2016). The initialized model investigated the reservoir performance with and without pressure maintenance over a twenty (20) year period. The original oil in place (OOIP) estimated by the model was 7% larger than the OOIP estimated by ExxonMobil for Liza field. The model produced 35% of the OOIP compared to 50% of OOIP as forecasted by the operators. (See Table 1). The factors that strongly influenced this outcome were, the well positioning and the water injection rates. A significant percentage of the oil remained unproduced in the lower layers of the model after the 20-year period. Time did not permit further modelling to improve the performance of the model. Table 1 Comparison of The Created Model and ExxonMobil's Proposal for Liza. Property ExxonMobil's statement on Liza field Modelled field Result Original Oil in Place (MMbbl) 896 967 Oil Recovery Factor (%) 50 35 Gas production from the model would be used as gas injection from three injector wells and as fuel for the proposed 200 MW power plant for Guyana. Even so, significant volumes of natural gas remained unallocated and subsequently a valuable resource may have to be flared.

scholarly journals Studying of changes in the interaction of well during the water injection process

2019 ◽  
pp. 81-85
Author(s):  
Damir K. Sagitov
Keyword(s):  
Correlation Coefficient ◽  
Pair Correlation ◽  
Water Injection ◽  
Reservoir Pressure ◽  
Maintenance System ◽  
Displacement Front ◽  
Injection Process ◽  
Production Wells

The study of the causes of changes in the effectiveness of the reservoir pressure maintenance system in terms of the interaction of injection and production wells is an important and insufficiently studied problem, especially in terms of the causes of the attenuation of stable connections between the interacting wells. Based on the results of the calculation of the Spearman pair correlation coefficient, the reasons for the change in the interaction of wells during the flooding process at various stages were estimated. Of particular interest are identified four characteristic interactions, which are determined by the periods of formation of the displacement front.

scholarly journals Geomechanical Modeling of Reservoir Compaction, Surface Subsidence, and Casing Damage at the Belridge Diatomite Field

2000 ◽  
Vol 3 (04) ◽  
pp. 348-359 ◽  
Author(s):  
J.T. Fredrich ◽  
J.G. Arguello ◽  
G.L. Deitrick ◽  
E.P. de Rouffignac
Keyword(s):  
Three Dimensional ◽  
Surface Subsidence ◽  
Reservoir Rock ◽  
Management Tool ◽  
High Porosity ◽  
Reservoir Pressure ◽  
Material Models ◽  
Reservoir Flow ◽  
Casing Damage ◽  
Contact Surfaces

Summary Geologic, and historical well failure, production, and injection data were analyzed to guide development of three-dimensional geomechanical models of the Belridge diatomite field, California. The central premise of the numerical simulations is that spatial gradients in pore pressure induced by production and injection in a low permeability reservoir may perturb the local stresses and cause subsurface deformation sufficient to result in well failure. Time-dependent reservoir pressure fields that were calculated from three-dimensional black oil reservoir simulations were coupled unidirectionally to three-dimensional nonlinear finite element geomechanical simulations. The reservoir models included nearly 100,000 gridblocks (100 to 200 wells), and covered nearly 20 years of production and injection. The geomechanical models were meshed from structure maps and contained more than 300,000 nodal points. Shear strain localization along weak bedding planes that causes casing doglegs in the field was accommodated in the model by contact surfaces located immediately above the reservoir and at two locations in the overburden. The geomechanical simulations are validated by comparison of the predicted surface subsidence with field measurements, and by comparison of predicted deformation with observed casing damage. Additionally, simulations performed for two independently developed areas at South Belridge, Secs. 33 and 29, corroborate their different well failure histories. The simulations suggest the three types of casing damage observed, and show that, although water injection has mitigated surface subsidence, it can, under some circumstances, increase the lateral gradients in effective stress that in turn can accelerate subsurface horizontal motions. Geomechanical simulation is an important reservoir management tool that can be used to identify optimal operating policies to mitigate casing damage for existing field developments, and applied to incorporate the effect of well failure potential in economic analyses of alternative infilling and development options. Introduction Well casing damage induced by formation compaction has occurred in reservoirs in the North Sea, the Gulf of Mexico, California, South America, and Asia.1–4 As production draws down reservoir pressure, the weight of the overlying formations is increasingly supported by the solid rock matrix that compacts in response to the increased stress. The diatomite reservoirs of Kern County, California, are particularly susceptible to depletion-induced compaction because of the high porosity (45 to 70%) and resulting high compressibility of the reservoir rock. At the Belridge diatomite field, located ~45 miles west of Bakersfield, California, nearly 1,000 wells have experienced severe casing damage during the past ~20 years of increased production. The thickness (more than 1,000 feet), high porosity, and moderate oil saturation of the diatomite reservoir translate into huge reserves. Approximately 2 billion bbl of original oil in place (OOIP) are contained in the diatomite reservoir and more than 1 billion bbl additional OOIP is estimated for the overlying Tulare sands. The Tulare is produced using thermal methods and accounts for three-quarters of the more than 1 billion bbl produced to date at Belridge.5 Production from the diatomite reservoir is hampered by the unusually low matrix permeability (typically ranging from 0.1 to several md), and became economical only with the introduction of hydraulic fracturing stimulation techniques in the 1970's.6 However, increased production decreased reservoir pressure, accelerated surface subsidence, and increased the number of costly well failures in the 1980's. Waterflood programs were initiated in the late 1980's to combat the reduced well productivity, accelerated surface subsidence, and subsidence-induced well failure risks. Subsidence rates are now near zero; however, the well failure rate, although lower than that experienced in the 1980's, is still economically significant at 2 to 6% of active wells per year. In 1994 a cooperative research program was undertaken to improve understanding of the geomechanical processes causing well casing damage during production from weak, compactable formations. A comprehensive database, consisting of historical well failure, production, injection, and subsidence data, was compiled to provide a unique, complete picture of the reservoir and overburden behavior.7,8 Analyses of the field-wide database indicated that two-dimensional approximations9–11 could not capture the locally complex production, injection, and subsidence patterns, and motivated large-scale, three-dimensional geomechanical simulations. Intermediary results for Sec. 33 that used preliminary reservoir flow and material models were reported earlier.8 This paper presents results for best-and-final simulations that used improved reservoir flow models, more sophisticated material models, and activated contact surfaces. The simulations were performed for two independently developed areas at South Belridge, Secs. 33 and 29.

Improved monitoring of acoustic emissions in concrete structures by multi-triggering and adaptive acquisition time interval

Measurement ◽  
2015 ◽  
Vol 59 ◽  
pp. 227-236 ◽  
Author(s):  
Francesco Lamonaca ◽  
Antonio Carrozzini ◽  
Domenico Grimaldi ◽  
Renato S. Olivito
Keyword(s):  
Concrete Structures ◽  
Acoustic Emissions ◽  
Acquisition Time ◽  
Time Interval

Stability and Compatibility of Cimetidine Hydrochloride and Aminophylline in Dextrose 5% in Water Injection

1988 ◽  
Vol 22 (7-8) ◽  
pp. 592-593 ◽  
Author(s):  
Richard J. Baptista ◽  
Francis P. Mitrano
Keyword(s):  
Chemical Stability ◽  
High Performance ◽  
Room Temperature ◽  
Color Change ◽  
Water Injection ◽  
Controlled Study ◽  
Time Interval ◽  
Direct Sunlight ◽  
Control Solution ◽  
And Control

A controlled study was conducted to assess the physical compatibility of cimetidine hydrochloride (HCl) and aminophylline and the chemical stability of an admixture of the two medications in dextrose 5% in water (D5W) injection, over 48 hours at room temperature. Three one-liter admixtures were prepared, each containing cimetidine HCl 1200 mg and aminophylline 500 mg in D5W. One liter of only cimetidine HCl 1200 mg in D5W and one liter of only aminophylline 500 mg in D5W served as controls. Samples drawn from the five admixtures and immediately frozen were analyzed for cimetidine and theophylline content at times 0, 1, 6, 24, and 48 hours using high-performance liquid chromatography. Chemical stability of each drug was assessed relative to its time-zero concentration. Samples were also drawn from each test and control solution at every time interval to assess the pH. Admixtures were stored at room temperature out of direct sunlight for the duration of the study, and were visually inspected for color change, turbidity, cloudiness, and precipitation. Recovery of cimetidine and theophylline at all test intervals, pH assessments, and visual inspections of the admixtures showed that cimetidine HCl and aminophylline are both chemically stable and physically compatible for 48 hours at room temperature in one liter of D5W.

scholarly journals RESERVOIR PRESSURE MAINTENANCE BY WATER INJECTION INTO HORIZONTAL WELLS AT THE CONDITION OF THE GEOLOGICAL UNCERTAINTY IN CONTINENTAL DEPOSITS OF HIGH-VISCOSITYOIL OF PK1-3 FORMATION OF THE VOSTOCHNO-MESSOYAKHSKOYE OIL FIELD

2018 ◽  
pp. 44-50
Author(s):  
I. V. Kovalenko ◽  
S. K. Sokhoshko ◽  
N. N. Pleshanov
Keyword(s):  
Water Injection ◽  
Horizontal Wells ◽  
Oil Field ◽  
Reservoir Pressure ◽  
Geological Uncertainty ◽  
Continental Deposits

The article considers the problem of correct organization of the system of reservoir pressure maintenance by water injection into PK1-3 formation of the Vostochno-Messoyakhskoye oil field that has many geological uncertainties. To remove these uncertainties the authors offered the pilot well program of flooding system and detailed proposals for data diagnosis obtained during this program that will help to determine the most correct approach to the flooding system for this type of reservoirs.

scholarly journals Dynamics of water injection in an oil-wet reservoir rock at subsurface conditions: Invasion patterns and pore-filling events

2020 ◽  
Vol 102 (2) ◽  
Author(s):  
Abdulla Alhosani ◽  
Alessio Scanziani ◽  
Qingyang Lin ◽  
Sajjad Foroughi ◽  
Amer M. Alhammadi ◽  
...  
Keyword(s):  
Water Injection ◽  
Reservoir Rock ◽  
Pore Filling ◽  
Invasion Patterns

First Successful Proppant Frac in a Water Injection Field Strategy, West Qurna-1, South Iraq

2022 ◽  
Author(s):  
Erfan Mustafa Al lawe ◽  
Adnan Humaidan ◽  
Afolabi Amodu ◽  
Mike Parker ◽  
Oscar Alvarado ◽  
...  
Keyword(s):  
Water Injection ◽  
Injection Rate ◽  
Fracture Model ◽  
Productivity Index ◽  
Base Line ◽  
Reservoir Pressure ◽  
Injection Strategy ◽  
Injection Test ◽  
Step Rate ◽  
Step Down

Abstract Zubair formation in West Qurna field, is one of the largest prolific reservoirs comprising of oil bearing sandstone layers interbedded with shale sequences. An average productivity index of 6 STB/D/psi is observed without any types of stimulation treatment. As the reservoir pressure declines from production, a peripheral water injection strategy was planned in both flanks of the reservoir to enhance the existing wells production deliverability. The peripheral injection program was initiated by drilling several injectors in the west flank. Well A1 was the first injector drilled and its reservoir pressure indicated good communication with the up-dip production wells. An injection test was conducted, revealing an estimated injectivity index of 0.06 STB//D/psi. Candidate well was then re-perforated and stimulated with HF/HCl mud acid, however no significant improvement in injectivity was observed due to the complex reservoir mineralogy and heterogeneity associated to the different targeted layers. An extended high-pressure injection test was performed achieving an injectivity index of 0.29 STB/D/psi at 4500 psi. As this performance was sub-optimal, a proppant fracture was proposed to achieve an optimal injection rate. A reservoir-centric fracture model was built, using the petrophysical and geo-mechanical properties from the Zubair formation, with the objective of optimizing the perforation cluster, fracture placement and injectivity performance. A wellhead isolation tool was utilized as wellhead rating was not able to withstand the fracture model surface pressure; downhole gauges were also installed to provide an accurate analysis of the pressure trends. The job commenced with a brine injection test to determine the base-line injectivity profile. The tubing volume was then displaced with a linear gel to perform a step-rate / step-down test. The analysis of the step-rate test revealed the fracture extension pressure, which was set as the maximum allowable injection pressure when the well is put on continuous injection. The step-down test showed significant near wellbore tortuosity with negligible perforation friction. A fracture fluid calibration test was then performed to validate the integrated model leak-off profile, fracture gradient and young’s modulus; via a coupled pressure fall-off and temperature log analysis. Based on the fluid efficiency, the pad volume was adjusted to achieve a tip screen-out. The job was successfully pumped and tip screen-out was achieved after pumping over ~90% of the planned proppant volume. A 7 days post-frac extended injection test was then conducted, achieving an injection rate of 12.5 KBWD at 1300 psi with an injectivity index of 4.2 STB/D/psi. These results proved that the implementation of a reservoir-centric Proppant Fracture treatment, can drastically improve the water injection strategy and field deliverability performance even in good quality rock formations. This first integrated fracture model and water injection field strategy, represents a building platform for further field development optimization plans in Southern Iraq.

Sign in / Sign up

Export Citation Format

Share Document