Showing posts with label Oil Gas. Show all posts
Showing posts with label Oil Gas. Show all posts

Friday, 9 October 2015

Process Piping & Pipelines System



 

One of the most important components of the infrastructure in the industrialized world is the vast network of pipelines and process piping—literally millions and millions of miles. The term “pipelines” generally refers to the network of pipelines that transport water, sewage, steam, and gaseous and liquid hydrocarbons from sources (e.g., reservoirs, steam plants, oil and gas wells, refineries) to local distribution centers (“transmission pipelines”), and to the network of pipelines that distribute such products to local markets and end users (“distribution” pipelines). The term “process piping” generally refers to the system of pipes that transport process fluids (e.g., air, steam, water, industrial gases, fuels, chemicals) around an industrial facility involved in the manufacture of products or in the generation of power. Pipelines and process piping are generally made of steel, cast iron, copper, or specialty metals in certain highly aggressive environments, but the use of plastic materials is growing, especially in hydrocarbon-based distribution lines and in sewer lines. Very large-diameter water transmission lines are often made of reinforced concrete.

The most common method of joining the individual segments of pipe is by welding (or soldering in the case of copper, and gluing in the case of plastics), although bolted flanges or threaded connections are often used in smaller-diameter process piping. In low-pressure piping systems that transport non-hazardous fluids like water and sewage, mechanical joints (e.g., “ball and spigot,” compression) that rely on friction are commonly used. Pipelines and piping are usually constructed and maintained in accordance with national and local regulations and applicable industry standards. For example, the most commonly used industrial code for the transport of liquids is ASME B31.4. B31.8 is most commonly used for the transmission and distribution of gas, and ASME B31.3 most often applies to process piping. Once assembled, pipelines are usually buried, but process piping is usually above ground.

Pipelines and process piping are the safest means to transport gases and fluids across countries or across manufacturing facilities. However, given the extensive network of pipelines and piping, failures do occur, which can be quite spectacular and lead to extensive property damage and loss of life. Given their potential impact, it is important to investigate the cause(s) of such failures, which often involve input from many different engineering and scientific disciplines. As such, Exponent, with its broad range of skill sets, is uniquely positioned to investigate such failures, and has done so on hundreds of occasions, ranging from quarter-inch process tubing to 20-ft-diameter concrete water distribution pipelines.

Equally important, of course, is the prevention of pipeline and piping failures. Our scientists and engineers provide in-depth technical knowledge that has enabled us to make significant contributions to clients during the design, layout, and construction of pipelines and piping systems, and in the development and implementation of integrity and risk management programs. Exponent staff has brought their expertise to bear on preventive projects ranging in scope from reviewing the design and construction of the process piping at petrochemical plants to overall integrity reviews of long-distance oil and gas transmission pipeline systems.

Clients that have utilized Exponent’s pipeline and process piping expertise have included Fortune 500 manufacturing and petrochemical companies, utilities, pipeline companies, insurers, and capital project lending organizations.
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Wednesday, 30 September 2015

Onshore & Offshore Structures & Systems

Onshore Structures and Systems
 
Exponent is actively involved in providing risk assessment services for owners and operators of onshore petrochemical process facilities. These assessments focus on naturally occurring hazards such as hurricanes and earthquakes, and also on man-made hazards like vapor-cloud explosions. The scope of services provided by Exponent includes probabilistic and deterministic hazard definitions, onsite inspections, structural and material load and stress analyses using advanced modeling tools, vulnerability determinations, probable maximum loss estimations for property and business, and mitigation planning. The broad range of expertise among our staff enables us to conduct such assessments in a thorough and timely manner. The benefits of our multidisciplinary approach include better understanding of employee exposures to potentially hazardous situations, improved knowledge of asset vulnerabilities, identification of opportunities for cost-effective mitigation measures to reduce potential losses, and more thorough assessment of loss exposures from an insurance perspective.
Offshore Structures and Systems 
 
Exponent can assist offshore oil and gas operators with determination of load capacities and performance levels for a range of fixed and floating production or storage systems. These services include using advanced modeling tools to conduct structural analyses of platform systems or components, from caisson wellheads to drilling derricks, in accordance with the latest American Petroleum Institute best practices and specifications. Our analytical expertise and capabilities also include pipelines and well completion (casing and tubing). We have extensive expertise in materials testing, modeling, and thermal load analysis, which are important considerations when dealing with the extreme operating environments often encountered by oil and gas operators. Several of Exponent’s senior technical staff have previous work experience with major energy companies, and therefore are familiar with the needs and challenges faced by the offshore industry.
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Sunday, 30 August 2015

Oil and gas exploration, and production life cycle

Oil and gas exploration, and production life cycle
Cairn looks to create, add and realise value for stakeholders, but not at the expense of the safety and well-being of people and the environment. We manage the risks associated with our business responsibly for all our activities and wherever we operate. This means, we aim to behave professionally in our dealings with people and within the environment from the very start of any project or activity.
The oil and gas business is, by nature, long-term and our approach covers every stage of the oil and gas life-cycle and is outlined below.


1. Due diligence
Before making an acquisition or investment, applying for an exploration licence or farming-in to an existing project, Cairn carries out an extensive risk-screening process which includes assessing whether there are potential health and safety, social, human rights, political, corruption, security or environmental impacts. This is used in decision-making on whether or not to proceed and if investment goes ahead it informs approaches to risk management going forward.
In 2014 we conducted due diligence on farm-in opportunities including the Mesana blocks in Spain.  We farmed-in to the PL420 block and drilling project operated by Statoil in the Norwegian sector of the North Sea. We also farmed out of UK sector blocks P2040 and P2086, reducing our interests south of Catcher.
2. Prequalification
When we apply for an exploration licence, the necessary documents are submitted to the relevant authorities. Typically this includes information about our legal status, financial capability, technical competence and plans to manage health, safety and environmental risks, and contributions to local economic development.
In 2014 Cairn participated in the 23rd licensing round in the Barents Sea, Norway.
3. Exploration seismic
Once Cairn has been awarded the right to explore in a certain area, we may carry out seismic surveys to develop a picture of geological structures below the surface. This helps identify the likelihood of an area containing hydrocarbons. Seismic surveys are usually preceded by an assessment of environmental, social and human rights impacts, which are managed through the Project Delivery Process (PDP).
During 2014 Cairn successfully completed seismic surveys offshore the Republic of Ireland and Malta. As non-operator, we also participated in seismic operations offshore Western Sahara.  Application for seismic surveys is pending offshore the Gulf of Valencia.
4. Site survey
Before commencing any drilling activity, site surveys are carried out to gain more detailed information on the area where an exploration well may be drilled, and to confirm that the selected drilling location is safe and that any sensitive environments can be avoided.
The process normally involves taking geological samples from the seabed and carrying out shallow seismic surveys. These activities have low social and environmental impacts and therefore usually do not require a separate Environmental Impact Assessment (EIA) or Social Impact Assessment (SIA).
Pre- and post-drilling surveys were completed for wells offshore Senegal and following drilling offshore Morocco.
5. Exploration drilling
Exploration wells are drilled to determine whether oil or gas is present. This phase can be accompanied by a step-change in activity and visibility to local people as offshore exploration can involve a drilling rig, supply vessels and helicopters for transporting personnel.
Exploration drilling is preceded by an assessment to understand potential health, safety, environmental, social, security and human rights impacts. These assessments identify appropriate steps to reduce impacts, manage risks and assist in operating responsibly. Limited community development programmes may also be put into place at this time depending on the nature of the programme.
In 2014 we continued our exploration drilling campaign offshore Morocco, and initiated and completed an exploration drilling campaign offshore Senegal. We were also involved, as non-operator, in exploration drilling in the UK and Norwegian North Sea. Drilling in the Cap Boujdour block, offshore Western Sahara, commenced in December 2014.
6. Appraisal drilling
If promising amounts of oil and gas are confirmed during the exploration phase, field appraisal is used to establish the size and characteristics of the discovery and to provide technical information to determine the optimum method for recovery of the oil and gas. The potential social and environmental impacts associated with appraisal drilling are comparable to exploration drilling, and similar assessments are carried out in advance.
Due to the delay in refurbishment of the Blackford Dolphin rig, the proposed Spanish Point appraisal well, offshore Republic of Ireland, could not be drilled in 2014 during the safe weather window and was therefore postponed. Plans are well advanced to drill this well, subject to the necessary approvals.  Preparation for anticipated appraisal drilling in Senegal is also underway.
7. Development
If appraisal wells show technically and commercially viable quantities of oil and gas, a development plan is prepared and submitted to the relevant authorities for approval. This includes a rigorous assessment of all the potential risks and a long-term assessment of environmental and social impacts covering a timeframe of between 10 and 30 years. The plan will also detail projected benefits to local communities, for example employment and supplier opportunities, as well as proposing how to manage potential impacts such as an influx of workers from outside the local community. At this stage good design is important to remove and mitigate risks to an acceptable level as well as managing construction and installation in a manner to likewise minimise impacts.
We are participating as non-operator in two development projects, the Kraken and Catcher fields, in the UK North Sea.
8. Production
A variety of options are available for the production of oil and gas. During this phase, which can last many decades, regular reviews are made of social and environmental performance to ensure that impacts identified in the assessments are mitigated. Changes in the risks associated with activities are assessed throughout the production period. Safe operations remain an ongoing requirement at this stage, which means personnel are competent and good HSE behaviours are in place and equipment is properly maintained and operated.
We currently have no operated production, but historically had significant production through our Indian business, Cairn India Limited (CIL), which we subsequently exited. Our involvement in exploration, and latterly production in India, brought social and economic development to a number of regions.
We anticipate production from our non-operated Catcher and Kraken fields from 2016/2017.
9. Decommissioning
This phase occurs when hydrocarbons can no longer be extracted safely or economically at the end of any field life-cycle. Decommissioning consists of closing operations in a manner that protects people and the environment and to avoid unacceptable legacy issues for local stakeholders and the Company. We are not engaged in any decommissioning activities at this time.

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Tuesday, 4 August 2015

Oil Spill Assessment

 
Exponent scientists have more than 40 years of experience in assessing the impacts associated with oil spills, providing consulting services to most of the major international oil companies, as well as pipeline, oilfield engineering design and service companies. In addition, our scientists have supported U.S. and international governments in responding to and assessing spill impacts.
Our services include:
  • Emergency environmental response - cleanup and monitoring chemistry 
    • Source characterization/fingerprinting 
    • Contamination assessment 
    • Background and baseline assessment 
  • Monitoring and NRDA 
    • Exposure and bioavailability assessment 
    • Shoreline surveys and ecology studies - impact and recovery 
    • Restoration 
  • Database development 
  • Geospatial analyses 
  • Training
Emergency Environmental Response – Cleanup Monitoring Chemistry
Rapid environmental response is critical to the effective oil spill management. Exponent scientists are on call for immediate response to oil spill incidents. Our response experience focuses on environmental monitoring, assistance to spill clean-up efforts, ephemeral sampling and hydrocarbon chemistry. In complex cases involving releases into urban estuaries or industrial settings a strong scientific approach is critical to reconstructing the release, assessing injury, establishing causation, and defining the baseline. Our scientists and engineers excel in the area of source characterization and petroleum fingerprinting, and our clients rely on our combined experience in petroleum fate in the environment to accurately assess impacts and allocate those impacts to various sources.
Monitoring and Natural Resource Damage Assessment (NRDA) 

One of Exponent’s core, signature business areas is that of NRDA. Exponent has been a pioneer and a trusted consultant on NRDA issues since the first regulations were developed. Our team has unparalleled experience and depth in supporting industry in the area of NRDAs under the Oil Pollution Act (OPA), and under state claims. The fate of spilled oil in the environment must be understood in order to predict the potential for exposure of ecological receptors. Exponent’s team of petroleum chemists and toxicologists have extensive experience with determining exposures associated with oil spills, as well as issues related to the persistence and bioavailability of oil in the environment, and the use of biomarkers as measures of exposure. Our clients rely on our combined experience in contaminant assessment and biological injury assessment, along with our knowledge of transport pathways to help assess injury and allocate those injuries to various sources.
Geospatial Analysis
Exponent scientists have evaluated the geospatial implications of different oil spill response strategies on shoreline impacts. Our work has focused on the development of a GIS from base shoreline maps obtained from aerial photographs. The analysis of possible shoreline impacts from oil spills relies, in part, on the type of shoreline being affected. Our team of aerial imagery and GIS specialists evaluated the shoreline typing, and have determined that the usability of aerial photographs to populate a GIS system, and hence to assess oil spill impact and persistence, is highly dependent on the timing and quality of the aerial images. This finding is especially important when it comes to the timing of tides and image acquisition where significant offsets and errors in shoreline typing can occur without such recognition. 
 
Database Development
Exponent has developed a customizable database and interface to store, summarize, and display environmental data from a wide variety of sites and investigations, and has been customized for oil spills. Analytical data, photographs, chromatograms, and scanned documents can be linked to individual data points. The database has a web-tool protected interface that is setup for individual users and includes customized data selection tools which allow simplified searches, selection and download of data sets based on end-user needs. The data output(s) from the database can be Access or Excel format spreadsheets that can be downloaded by the user for further data analysis and interpretation. Thus no knowledge of Access will is required of the end-users.
Training
Exponent scientists have conducted oil spill training programs and seminars for clients worldwide. The training includes all of the environmental issues and response strategies and methods that are part of the short and long term response efforts. Our primary focus is on environmental sampling, NRDA, environmental monitoring and chemical fingerprinting, but also includes shoreline assessment, toxicity assessment and other oil spill related issues.
Exponent Oil Spill Experience
  • Amoco Cadiz 
  • Argo Merchant
  • Bayway Refinery (Arthur Kill)
  • Cosco Busan 
  • Deepwater Horizon
  • Ever Reach
  • Exxon Valdez
  • Haven
  • Ixtoc I
  • Katina
  • Kure
  • Kuroshima
  • Martinez Refinery (Suisun Bay)
  • New Carissa
  • Newton Lake
  • North Cape
  • Perth Amboy (Arthur Kill)
  • Prestige
  • ROPME Sea
  • Tsesis 
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