High Rate and High Temperature Fracture Behaviour of Polycrystalline Diamond

Polycrystalline diamond (PCD) materials have a variety of applications, mainly as cutting tools for machining non-ferrous metals and non-metallic materials. A significant application of PCD is in oil and gas industry for rock drilling operations. Other important areas, such as mining, have yet to reach their full potential. These cutters/tools are subjected to high operating temperatures, impact loads and abrasive wear during these operations, which may lead to their sudden failure. An advantage of these materials is that their structure and composition can be engineered to return properties required for specific applications and operations.

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EVOLUTION OF THE QUALITY OF HIGH-PRESSURE VALVES DURING THE PERIOD OF THEIR INTENSIVE DEVELOPMENT

ETM Equipment, Technologies, Materials ◽

10.36962/etm0501202004 ◽

2021 ◽

Vol 05 (01) ◽

pp. 04-10

Author(s):

Sabir Babaev ◽

Ibrahim Habibov ◽

Zohra Abiyeva

Keyword(s):

High Pressure ◽

Oil And Gas ◽

Oil And Gas Industry ◽

Machine Building ◽

High Rate ◽

Performance Criteria ◽

Gas Industry ◽

Evolution Of Technology ◽

Intensive Development

Prospects for the further development of the oil and gas industry are mainly associated with the development and commissioning of high-rate fields. In this regard, the production of more economical and durable equipment by machine-building enterprises, an increase in the level of its reliability and competitiveness, as well as further improvement of technological production processes, is of paramount importance. The evolution of technology in a broad sense is a representation of changes in designs, manufacturing technology, their direction and patterns. In this case, a certain state of any class of TC is considered as a result of long-term changes in its previous state; transition from existing and applied in practice vehicles to new models that differ from previous designs. These transitions, as a rule, are associated with the improvement of any performance criteria or quality indicators of the vehicle and are progressive in nature. The work is devoted to the study of the evolution of the quality of high-pressure valves during the period of their intensive development. Keywords: technical system, evolution of technology, high-pressure valves, shut-off devices, gate.

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RAM analysis of dynamic positioning system: An approach taking into account uncertainties and criticality equipment ratings

Proceedings of the Institution of Mechanical Engineers Part O Journal of Risk and Reliability ◽

10.1177/1748006x211051805 ◽

2021 ◽

pp. 1748006X2110518

Author(s):

Maria V Clavijo ◽

Adriana M Schleder ◽

Enrique Lopez Droguett ◽

Marcelo R Martins

Keyword(s):

Oil And Gas ◽

Oil And Gas Industry ◽

Economic Losses ◽

Gas Industry ◽

Dynamic Positioning System ◽

Failure Data ◽

Total Failure ◽

Drilling Operations ◽

Maintainability Analysis ◽

Ram Analysis

Currently, a Dynamic Position (DP) System is commonly used for offshore operations. However, DP failures may generate environmental and economic losses; thus, this paper presents the Reliability, Availability and Maintainability (RAM) analysis for two different generations of DP system (DP2 and DP3) used in drilling operations. In addition to the RAM analysis, the approach proposed herein considers the uncertainties present in the equipment failure data and provides more information about criticality equipment ratings and probability density functions (pdf) of the repair times. The reliability analysis shows that, for 3 months of operation, the total failure probability of the DP2 system is 1.52% whereas this probability for the DP3 system is only 0.16%. The results reveal that the bus-bar is the most critical equipment of the DP2 system, whereas the wind sensor represents the priority equipment in the DP3 system. Using 90% confidence level, each DP configuration was evaluated for a 1-year operation, finding a reliability mean equal to 70.39% and 86.77% for the DP2 system and the DP3 system, respectively. The DP2 system asymptotic availability tends to present a constant value of 99.98% whereas for the DP3 system, it tends to be 99.99%. Finally, the maintainability analysis allows concluding that the mean time for system repair is expected to be 3.6 h. This paper presents a logical pathway for analysts, operators, and reliability engineers of the oil and gas industry.

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An Analytical Framework for Resilience Exemplified With a Real-Time Operational Center

ASCE-ASME J Risk and Uncert in Engrg Sys Part B Mech Engrg ◽

10.1115/1.4044786 ◽

2019 ◽

Vol 6 (1) ◽

Author(s):

Grethe O. Ose ◽

Trygve J. Steiro

Keyword(s):

Change Process ◽

Oil And Gas ◽

Data Gathering ◽

Oil And Gas Industry ◽

Analytical Framework ◽

Gas Industry ◽

Drilling Operations ◽

Pros And Cons ◽

Integrated Operations ◽

Technological Opportunities

Abstract Integrated operations (IO) is an ongoing change process in the oil and gas industry. New technological opportunities enable working in new ways that involve an integration of onshore and offshore personnel. This paper analyzes the results of two rounds of data gathering in an onshore drilling support center, in terms of the development of resilience. The first round took place in 2004/2005 and the second in 2012. This study presents a framework for the analysis of resilience and has used the case company as a mean of testing the framework. Our findings indicate that the support center has taken a huge step in the direction of becoming more resilient. The drilling company has tested a number of designs and sizes of support centers, each of which has different pros and cons. For the drilling discipline to develop resilience, it is essential that the number of rigs supported by a center is not too large, as they must not become involved in too many rigs and drilling operations. Our findings also indicate that the suggested framework provides a good overall picture of the development of resilience in the case company.

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Logic Sequence Prevents Launching Devices Downhole Out of Sequence

Volume 1A: Offshore Technology ◽

10.1115/omae2014-23167 ◽

2014 ◽

Author(s):

Ricardo de Lepeleire ◽

Nicolas Rogozinski ◽

Hank Rogers ◽

Daniel Ferrari

Keyword(s):

Latin America ◽

Oil And Gas ◽

New Technology ◽

Specific Area ◽

Oil And Gas Industry ◽

Gas Industry ◽

Logic Control ◽

Drilling Operations ◽

Common Operation ◽

Increasing Demand

Within the oil and gas industry, significant costs are often incurred by the operating company during the well-construction phase of drilling operations. Specifically, the operators cost to drill a well can cost tens or hundreds of millions of USD. One specific area where significant changes in drilling operations have occurred is in the offshore environment, specifically operations from mobile offshore drilling units (MODUs). With the ever-increasing demand for oil and gas, operators globally have increased drilling budgets in an effort to meet forecasted demand. However, the increased budgets are often eroded or offset by increasing drilling costs. Therefore, operators are continually in search of new technology, processes, or procedures to help improve drilling operations and overall operational efficiencies. One Latin America operator identified a common operation as a possible area where operational cost could be easily reduced through the implementation of systems that allow the manipulation of valve manifolds remotely. Additionally, operating such valve manifolds remotely enhanced operational safety for personnel, which was an equally important consideration. This paper details the evaluation of existing equipment and procedures and a process used to develop a new remote-control system using a machine logic control (MLC) that has been designed, built, tested, and deployed successfully on MODUs operating in Latin America.

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OIL AND GAS INDUSTRY IN WESTERN AUSTRALIA

The APPEA Journal ◽

10.1071/aj98002 ◽

1999 ◽

Vol 39 (1) ◽

pp. 30

Author(s):

M. Meaton

Keyword(s):

Western Australia ◽

Oil And Gas ◽

Oil And Gas Industry ◽

Gas Production ◽

The State ◽

Full Potential ◽

Gas Industry ◽

Oil And Gas Production ◽

Advantages And Disadvantages ◽

Petroleum Companies

The oil and gas production sector in Western Australia has grown dramatically in recent years and now represents the largest resource sector in the State economy. The industry has a very promising future but it faces a number of challenges if it is to achieve its full potential. Its production location in remote parts of the State confers both advantages and disadvantages. Chief among the disadvantages is the challenge of convincing the community and government of the benefits from the industry when many of those benefits are not apparent to the majority of the population. The emphasis in this paper is on economic impacts, social benefits and community attitudes.WA has produced about 820 million barrels of oil and 2000 million barrels of natural gas when gas is calculated in energy equivalent terms. Petroleum energy production has increased dramatically over the last 15 years and the State is now a substantial energy exporter. Petroleum sources provide the energy for over 85% of the final energy used in the State. Total industry investment over the last 18 years has been nearly $21,000 million for an average of $3.2 million each day. Direct employment by petroleum companies is around 2,500 people with flow-on employment in the services sector estimated at over 17,000 people. Petroleum companies have been major contributors to government revenue and to the development of remote regions in WA.

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The Challenges of Multiphase Flow Metering: Today and Beyond

Volume 2: Structures, Safety and Reliability; Petroleum Technology Symposium ◽

10.1115/omae2007-29527 ◽

2007 ◽

Cited By ~ 1

Author(s):

Gioia Falcone ◽

Claudio Alimonti

Keyword(s):

Multiphase Flow ◽

Oil And Gas ◽

Oil And Gas Industry ◽

Black Box ◽

Full Potential ◽

Gas Industry ◽

Individual Measurement ◽

Flow Metering ◽

Wet Gas ◽

The Impact

Since the early 1990’s, when the first commercial meters started to appear, Multiphase Flow Metering (MFM) has grown from being an area of R&D to representing a discipline in its own right within the oil and gas industry. The total figure for MFM installations worldwide is now over 1,800. Field applications include production optimisation, wet gas metering, mobile well testing and production allocation. However, MFM has not yet achieved its full potential. Despite an impressive improvement in the reliability of sensors and mechanical parts (particularly for subsea installations) over the past few years, there remain unresolved questions regarding the accuracy and range of applicability of today’s MFM technology. There is also a tendency to forget the complexity of multiphase flow and to evaluate the overall performance of a MFM as a “black box”, often neglecting all the possible uncertainties that are inherent in each individual measurement solutions. This paper reviews the inherent limitations of some classical MFM techniques. It highlights the impact of instruments rangeability, empirical correlations for pressure drop devices and fluids characterisation on the error propagation analysis in the “black box”. It also provides a comprehensive review of wet gas definitions for the oil and gas industry. Several attempts have been made to define “wet gas” for the purpose of metering streams at high gas-volume-fractions, but a single definition of wet gas still does not exist. The measurement of multiphase flows presents unique challenges that have not yet been fully resolved. However, the challenges are exciting and the authors have no doubts that new milestones will soon be set in this area. Today’s MFM technology has already become one piece of the optimised production system jigsaw. MFM has succeeded in fitting with other technologies toward global field-wide solutions. The ideal MFM of the future is one that provides unambiguous measurements of key parameters from which the flow rates can be deduced independently from flow regimes and fluid properties.

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Characterization of barite reserves in Nigeria for use as weighting agent in drilling fluid

Journal of Petroleum Exploration and Production Technology ◽

10.1007/s13202-021-01164-8 ◽

2021 ◽

Vol 11 (5) ◽

pp. 2157-2178

Author(s):

David Oluwasegun Afolayan ◽

Adelana Rasak Adetunji ◽

Azikiwe Peter Onwualu ◽

Oghenerume Ogolo ◽

Richard Kwasi Amankwah

Keyword(s):

Specific Gravity ◽

Oil And Gas ◽

Drilling Fluid ◽

Chemical Properties ◽

Oil And Gas Industry ◽

American Petroleum Institute ◽

Gas Industry ◽

Cu Content ◽

Hardness Scale ◽

Drilling Operations

AbstractSuccessful drilling operations are dependent on the properties of the drilling fluid used to drill wells. Barite is used as a weighting agent during the preparation of drilling fluid. Over the years, oil and gas industry in Nigeria has been depending mainly on imported barite for drilling operations, whereas the country has huge deposits of barite. There is the need to assess the properties of the locally sourced barite for their suitability in drilling fluid formulation. This study presents the local processing methods of barite and examines the crude and on-the-site processed barite’s physio-chemical properties. These parameters were compared with American Petroleum Institute and Department of Petroleum Resources standards. XRD results show that on-the-site beneficiated barite has 87.79% BaSO4, 6.66% silica, 0.03% total soluble salt, 1.39% Fe2O3, and 1.603% heavy metals. Chemical analysis indicated that the pH, moisture content, metallic content such as Ca, Pb, Zn, Mg, Cu, and Cd minerals, and extractable carbonates were within the standard specified for usage as a drilling fluid weighting agent. The analysed crude barite samples were basic, within the pH of 8.3 and 8.6. Locally processed barite has lower Fe, Pb, Cd, and Cu content compared to industrially accepted barite. The specific gravity increased from 4.02 ± 0.07 to 4.15 ± 0.13, and the hardness reduced potentially from 5 Mohr to 3.5 Mohr on the hardness scale. The amount of impurities was sufficiently low, and the specific gravity of the samples improved to meet the needs of any drilling operation and compare favourably with industrially accepted barite.

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Mitigating Twist-Offs While Drilling with the Help of BHA Dynamics Software

10.2118/202174-ms ◽

2021 ◽

Author(s):

Mario A. Rivas ◽

Andres A. Ramirez ◽

Bader S. Al-Zahrani ◽

Khaled K. Abouelnaaj

Keyword(s):

Oil And Gas ◽

Drill Pipe ◽

Oil And Gas Industry ◽

Parameters Optimization ◽

Gas Industry ◽

Drilling Parameters ◽

Resonance Vibrations ◽

Bottom Hole Assembly ◽

Drilling Operations ◽

Safe Operating

Abstract One of the major challenges the Oil and Gas Industry faces nowadays during drilling operations is the twist-offs on Bottom Hole Assembly (BHA) components such as Drilling Jars, Shock Tools, Mud Motors, Roller Reamers, Stabilizers, Drill Collars, PBLs, Heavy Weight Drill Pipe (HWDP), Drill Pipe (DP), etc. To overcome this challenge, an initiative was proposed by performing a study based on twist-offs experienced on BHA components while drilling operations and recommendations are provided to reduce and eliminate twist-offs related to drilling with suboptimal drilling parameters. The statistical data for the twist-off events was collected coming from Daily Drilling Reports, and the analysis was limited to all wells which presented twist-offs on the drillstring and BHA components. Three examples of twist-offs due to drilling with erratic torque are discussed as well as a successful example of drilling parameters optimization. The three examples which presented drillstring and BHA twist-offs were analyzed using available BHA Dynamics and vibrations software and it was discovered that the parameters utilized (operational RPM) fell within the critical zone shearing force peaks (resonance vibrations). The components with the most twist-offs were identified. The hole size where we have the most twist-offs were also identified, which will help in focusing on these areas for the recommendations provided. This analysis will help Drilling Engineers and Foremen to foresee vibration dysfunctions and act accordingly by the use of available BHA Dynamics software in order to optimize drilling parameters before and during drilling. By drilling within a safe operating RPM window (away from resonant RPM), there will be reduction in the number of twist-offs and associated lost time.

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Comprehensive Instrumentation of Two Offshore Rigs for Wellhead Fatigue Monitoring

Volume 3B: Structures, Safety and Reliability ◽

10.1115/omae2017-61291 ◽

2017 ◽

Cited By ~ 1

Author(s):

Svein Herman Nilsen ◽

Massimiliano Russo ◽

Guttorm Grytøyr

Keyword(s):

Real Time ◽

Structural Integrity ◽

Oil And Gas ◽

Oil And Gas Industry ◽

Quality Data ◽

Risk Level ◽

Gas Industry ◽

Accuracy Requirement ◽

Fatigue Monitoring ◽

Drilling Operations

Over the last decades, the complexity and duration of offshore drilling operations have steadily increased. The size and weight of the risers and BOP stack has grown significantly. These factors have led to an increase in fatigue loads imposed on the wellhead structures during drilling and completion operations. Wellhead fatigue might ultimately lead to loss of well structural integrity and pressure containment and therefore safe and reliable drilling of subsea wellheads has gained high priority in the global oil and gas industry. This paper presents two of the most complex real time instrumentation campaigns for drilling operations. Analyses of a connected drilling riser system including the well structure are complex and involve several engineering disciplines. In addition, there are many unknowns going into the equations when accumulated fatigue damage of the wellhead is estimated. Therefore, assumptions need to be made, very often on the conservative side. A typical example are the global drilling riser analyses where the environmental conditions, actual rig motion and riser / BOP behavior are uncertain. With the duplex scope of accurately documenting the wellhead fatigue status during drilling operations and of achieving a better understanding of the actual risk level of wellhead fatigue, Statoil decided to start a very comprehensive monitoring campaign. Two MODU representing very different generations of rigs in terms of weights and types of equipment were instrumented from topside to BOP connector. Strain gauges were installed around the BOP connector as close as possible to the wellhead in order to capture wellhead response as accurately as possible. Due to the large number of sensors, high accuracy requirement and high sampling frequency of data to be shown live, a cabled solution was selected vs remote battery operated sensors transmitting via acoustic. Double set of cables, sensors and topside equipment were installed in order to make the instrumentation system fully redundant and suited for permanent installation. All data were additionally made available real time onshore to allow the full overview of the operation. To author’s knowledge, these two instrumentation systems are the most comprehensive and complex of this type installed on a drilling riser as of today. The first of the two system was installed approximately three years ago and it is still in operation. This paper describes the instrumentation systems installed and gives an extract of the quality data extracted and already used in already published studies [1, 2, 3].

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Application of Numerical Modeling for Predicting the Fatigue Crack Growth of an Elliptical Crack in Kelly Valves

Volume 3: Design and Analysis ◽

10.1115/pvp2016-63306 ◽

2016 ◽

Author(s):

Hamidreza Ahmadimoghaddamseighalani ◽

Pierre Mertiny

Keyword(s):

Numerical Modeling ◽

Fatigue Life ◽

Oil And Gas ◽

Oil And Gas Industry ◽

Elliptical Crack ◽

Microsoft Excel ◽

Gas Industry ◽

Drilling Operations ◽

Python Programming ◽

Fea Analysis

Kelly valves, also known as full opening safety valves, are widely used in the oil and gas industry for the purpose of blowout prevention. Crack propagation in the stem hole feature of Kelly valves is of concern during service in drilling operations as fatigue may lead to catastrophic failure. A computational tool to predict the fatigue life of these valves when a crack is present was therefore created. The present paper describes the numerical modeling approach in which an elliptical crack in the stem hole feature was introduced. To predict the fatigue life of the valve based on the J-integral method, ANSYS Workbench was used for a FEA analysis in conjunction with Microsoft EXCEL and Iron Python programming.

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