Academic literature on the topic 'Leukaemia in the Australian petroleum industry'
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Journal articles on the topic "Leukaemia in the Australian petroleum industry"
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Hyde, Charles E. "Evaluating Mergers in the Australian Petroleum Industry." Economic Record 78, no. 242 (September 2002): 299–311. http://dx.doi.org/10.1111/1475-4932.00059.
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Molyneux, Simon. "PESA Australian business environment review 2019." APPEA Journal 60, no. 2 (2020): 360. http://dx.doi.org/10.1071/aj20009.
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This Petroleum Exploration Society of Australia review looks at the major issues that impacted the Australian petroleum business environment in 2019. While the petroleum business in 2020 has been combating an oil price slump and a global economic slowdown driven by the COVID-19 pandemic, 2019 will be remembered as a pivotal year in the petroleum industry. At a global level, climate change moved centre-stage with global protests, extensive media coverage and clear commitments from global players in the resource industry to become net-zero emitters of carbon. Oil prices averaged US$64/barrel for Brent, liquefied natural gas (LNG) prices fell and global CO2 emissions from power generation were flat for the first time. In Australia, petroleum production also increased, driven by LNG production, and Australia became the world’s largest producer of LNG, the world’s largest CO2 injection plant became operational and the regulatory system was tested by current operations and future drilling. Meanwhile, society’s relationship with the petroleum industry was reframed with the linking of extensive bushfires to climate change. This paper will describe each of these issues and frame the issues facing the industry in 2020 and beyond.
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Tormasi, T. "LONG-TERM PERSPECTIVES FOR THE AUSTRALIAN GAS INDUSTRY." APPEA Journal 28, no. 1 (1988): 348. http://dx.doi.org/10.1071/aj87029.
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Changes in the structure of a modern economy are a natural function of altered world and domestic economic circumstances. It is important that the instrument of change be the marketplace. Governments around the world have not demonstrated a superior ability to 'pick winners'. There are many instances where governments have used public funds to foster the development of particular industries only to find that, as a result of economic circumstances, the favoured industries' reliance on public funding becomes chronic. The Government's role should be to ensure that market signals are transmitted and received clearly.In Australia structural change in the economy has been a fairly slow process. This has been brought about by the numerous obstacles that have existed in the marketplace. These have meant that, not only were market signals distorted or delayed, but when received did not motivate appropriate responses. For example, labour market rigidities, inequitable taxation policies, a fixed exchange rate, together with State Government charges, have posed real impediments to implementing the necessary adjustments to the Australian economy.The Australian mining industry and the petroleum industry, in particular, have always been geared to the world market and have increasingly constituted an important component of the nation's export receipts. With regard specifically the petroleum industry, the world price downturn of the past few years and the Government's decision to drop its import parity pricing will result in major changes in the Australian industry, particularly in the exploration sector. These signals suggest a world oversupply of petroleum with the corollary that additional reserves are not needed. A resultant downturn in exploration could develop into an irrevocable reversal and jeopardise the nation's strategically important petroleum industry.In light of the diminished circumstances of the sector it is essential that the petroleum industry receives equal treatment regarding taxation and other Government imposts. Failure to remove the discriminations against petroleum and to impose a uniform structure will result in a misallocation of resources and the possibility of a permanent winding down in exploration.
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Gorton, Justin. "Australian onshore petroleum acreage release 2016." APPEA Journal 56, no. 1 (2016): 495. http://dx.doi.org/10.1071/aj15035.
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This paper compiles material from state and territory jurisdictions describing the location and resource potential of Australian onshore and coastal waters acreage to be made available for petroleum exploration in 2016. The Australian state and territory governments continue to support investment in the petroleum industry through the annual provision of land for exploration, which is promoted nationally and internationally. Technical assessments are provided with the release, which detail the potential for conventional and/or unconventional resources. The level of assessment will depend on exploration maturity, but may include a description of the geological setting, review of exploration history, summary of key results, and subsurface maps/sections. In addition to this, any updates on recent upstream developments and government initiatives, as well as present and future policy directions that relate to onshore petroleum exploration, may be described, particularly for jurisdictions that are not making land available this year. With global demand for gas—led by Asia—expected to grow at 2.6% annually between 2015 and 2025, investing in Australia’s petroleum and gas industry presents a significant opportunity to supply into this growing market.
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Wyld, Irene, and Bruce Godfrey. "RESEARCH WITH A PURPOSE IN THE AUSTRALIAN PETROLEUM INDUSTRY." APPEA Journal 34, no. 1 (1994): 373. http://dx.doi.org/10.1071/aj93034.
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Research—defined broadly as any activity in the concept to delivery continuum—is critical to the success of the present thrust for development of a competitive Australia. It provides the key to maintenance of existing competitive advantages, and the development of new competitive advantages both within Australia and in export markets. Nowhere is this more important than in the Australian petroleum industry (oil and gas). This industry contributes in the order of $10 billion annually to Australia's balance of trade. Yet until recently little research has been undertaken by Australian petroleum companies to support their exploration and production activities here.There is now recognition by Australian petroleum companies that research must be undertaken by them to support access to prospective areas, enhance exploration success, maximise production and minimise environmental damage. The contribution which research can make to the growth of the industry will only accrue if that research is targeted on priorities which meet the short, medium, and long-term needs of the industry. To define these priorities APEA, working in conjunction with ERDC, has produced a research and development strategy for the Australian upstream petroleum industry.The priorities resulting from this process cover the areas of exploration, production efficiencies, reservoir management, environmental effects and safety. Implementation of the strategy is occurring via ajoint Petroleum R&D Committee. ERDC's role in this process is to manage its investment in the projects resulting from the strategy to maximise the chances of successful implementation of the outcomes for the benefit of the industry and Australia.
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Haworth, Jeff. "Australian onshore petroleum acreage and releases 2017." APPEA Journal 57, no. 2 (2017): 345. http://dx.doi.org/10.1071/aj16256.
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This paper is a compilation of material from state and territory jurisdictions regarding onshore acreage and its availability for petroleum exploration in 2017. Australian state and territory governments continue to support investment in the petroleum industry through the provision of acreage for exploration, which is promoted nationally and internationally. Updates are provided on recent upstream developments and government initiatives. Present and future policy directions that relate to onshore petroleum exploration are described, particularly for jurisdictions that are not making land available this year. When the APPEA conference was last held in Perth, in 2014, the oil price and exploration outlook were very different from today. In 2016, the petroleum industry experienced the full impact of the downturn, with the price for oil reaching a low of under $27 USD/barrel (WTI) early in the year. Several companies departed the onshore, exploration was at a fifteen-year low and much acreage has been surrendered across Australia. However, 2017 is showing signs of improvement with oil prices in the mid-50s and some hope that the industry will turn the corner this year. Low levels of exploration activity may have implications for future domestic gas supplies, and rising gas prices are of concern to local manufacturing industries and consumers throughout Australia. However, this may present marketing opportunities for successful explorers.
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DORAN, JOHN. "THE AUSTRALIAN PETROLEUM EXPLORATION INDUSTRY IN A GLOBAL CONTEXT." APPEA Journal 33, no. 2 (1993): 63. http://dx.doi.org/10.1071/aj92047.
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Hartwell, John. "2009 Release of offshore petroleum exploration acreage." APPEA Journal 49, no. 1 (2009): 463. http://dx.doi.org/10.1071/aj08030.
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John Hartwell is Head of the Resources Division in the Department of Resources, Energy and Tourism, Canberra Australia. The Resources Division provides advice to the Australian Government on policy issues, legislative changes and administrative matters related to the petroleum industry, upstream and downstream and the coal and minerals industries. In addition to his divisional responsibilities, he is the Australian Commissioner for the Australia/East Timor Joint Petroleum Development Area and Chairman of the National Oil and Gas Safety Advisory Committee. He also chairs two of the taskforces, Clean Fossil Energy and Aluminium, under the Asia Pacific Partnership for Clean Development and Climate (AP6). He serves on two industry and government leadership groups delivering reports to the Australian Government, strategies for the oil and gas industry and framework for the uranium industry. More recently he led a team charged with responsibility for taking forward the Australian Government’s proposal to establish a global carbon capture and storage institute. He is involved in the implementation of a range of resource related initiatives under the Government’s Industry Action Agenda process, including mining and technology services, minerals exploration and light metals. Previously he served as Deputy Chairman of the Snowy Mountains Council and the Commonwealth representative to the Natural Gas Pipelines Advisory Committee. He has occupied a wide range of positions in the Australian Government dealing with trade, commodity, and energy and resource issues. He has worked in Treasury, the Department of Trade, Department of Foreign Affairs and Trade and the Department of Primary Industries and Energy before the Department of Industry, Science and Resources. From 1992–96 he was a Minister Counsellor in the Australian Embassy, Washington, with responsibility for agriculture and resource issues and also served in the Australian High Commission, London (1981–84) as the Counsellor/senior trade relations officer. He holds a MComm in economics, and Honours in economics from the University of New South Wales, Australia. Prior to joining the Australian Government, worked as a bank economist. He was awarded a public service medal in 2005 for his work on resources issues for the Australian Government.
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Smith, Lisa, and Brian Evans. "Changing petroleum engineering education to meet industry demands." APPEA Journal 50, no. 1 (2010): 309. http://dx.doi.org/10.1071/aj09018.
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The Department of Petroleum Engineering at Curtin University had its inception in 1998. For the last 10 years, it lectured the Masters in petroleum engineering course to local Australian and international students, graduating more than 200 students. The rapid increase in the price of oil during 2006/7 saw a sudden and substantial growth in industry employment opportunities, which resulted in the department losing over half of its staff to industry. At the same time, the supply of local students reduced to less than 10% of those taking the course. This loss in both student numbers and staff at the same time threatened the department’s future, and resulted in the need for a new focus to return the department to stability. A number of new initiatives were introduced, which included: bringing industry into the decision-making processes; introducing a new two-year Masters program to assist high quality migrant students obtain Australian permanent residency; increasing the advertising of petroleum engineering as a career option to schools and industry; linking with UNSW, UWA and Adelaide universities to establish a joint Masters program; introducing a new Bachelor’s degree in petroleum engineering; changing the block form of teaching to a semester-based form; and having the Commonwealth recognise the new Masters program for Commonwealth funding of Australian students as a priority pathway to a career as a petroleum engineer while the Bachelors program gathered momentum. This paper maps the positive changes made during 2008/9, which led to a 100% increase in student numbers, a 50% increase in staff to stabilise teaching, a 400% increase in active PhD students, and industry projects to deliver an increasing stream of high quality, industry-ready, graduate petroleum engineers over the next 10–20 years into the current ageing population where the average age of a petroleum engineer is 51.
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Glass, D. "Retrospective exposure assessment for benzene in the Australian petroleum industry." Annals of Occupational Hygiene 44, no. 4 (June 1, 2000): 301–20. http://dx.doi.org/10.1016/s0003-4878(99)00105-2.
Full textDissertations / Theses on the topic "Leukaemia in the Australian petroleum industry"
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Glass, Deborah Catherine, and mikewood@deakin edu au. "Exposure estimation, uncertainty and variability in occupational hygiene retrospective assessment." Deakin University. School of Biological and Chemical Sciences, 1999. http://tux.lib.deakin.edu.au./adt-VDU/public/adt-VDU20051017.142634.
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This thesis reports on a quantitative exposure assessment and on an analysis of the attributes of the data used in the estimations, in particular distinguishing between its uncertainty and variability.
A retrospective assessment of exposure to benzene was carried out for a case control study of leukaemia in the Australian petroleum industry. The study used the mean of personal task-based measurements (Base Estimates) in a deterministic algorithm and applied factors to model back to places, times etc for which no exposure measurements were available. Mean daily exposures were estimated, on an individual subject basis, by summing the task-based exposures. These mean exposures were multiplied by the years spent on each job to provide exposure estimates in ppm-years. These were summed to provide a Cumulative Estimate for each subject.
Validation was completed for the model and key inputs.
Exposures were low, most jobs were below TWA of 5 ppm benzene. Exposures in terminals were generally higher than at refineries. Cumulative Estimates ranged from 0.005 to 50.9 ppm-years, with 84 percent less than 10 ppm-years.
Exposure probability distributions were developed for tanker drivers using Monte Carlo simulation of the exposure estimation algorithm. The outcome was a lognormal distribution of exposure for each driver. These provide the basis for alternative risk assessment metrics e.g. the frequency of short but intense exposures which provided only a minimal contribution to the long-term average exposure but may increase risk of leukaemia.
The effect of different inputs to the model were examined and their significance assessed using Monte Carlo simulation. The Base Estimates were the most important determinant of exposure in the model. The sources of variability in the measured data were examined, including the effect of having censored data and the between and within-worker variability. The sources of uncertainty in the exposure estimates were analysed and consequential improvements in exposure assessment identified.
Monte Carlo sampling was also used to examine the uncertainties and variability associated with the tanker drivers' exposure assessment, to derive an estimate of the range and to put confidence intervals on the daily mean exposures. The identified uncertainty was less than the variability associated with the estimates.
The traditional approach to exposure estimation typically derives only point estimates of mean exposure. The approach developed here allows a range of exposure estimates to be made and provides a more flexible and improved basis for risk assessment.
Books on the topic "Leukaemia in the Australian petroleum industry"
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Hook, Sharon, Graeme Batley, Michael Holloway, Paul Irving, and Andrew Ross, eds. Oil Spill Monitoring Handbook. CSIRO Publishing, 2016. http://dx.doi.org/10.1071/9781486306350.
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Oil spills can be difficult to manage, with reporting frequently delayed. Too often, by the time responders arrive at the scene, the slick has moved, dissolved, dispersed or sunk. This Oil Spill Monitoring Handbook provides practical advice on what information is likely required following the accidental release of oil or other petroleum-based products into the marine environment.
The book focuses on response phase monitoring for maritime spills, otherwise known as Type I or operational monitoring. Response phase monitoring tries to address the questions – what? where? when? how? how much? – that assist responders to find, track, predict and clean up spills, and to assess their efforts. Oil spills often occur in remote, sensitive and logistically difficult locations, often in adverse weather, and the oil can change character and location over time. An effective response requires robust information provided by monitoring, observation, sampling and science.
The Oil Spill Monitoring Handbook completely updates the Australian Maritime Safety Authority’s 2003 edition of the same name, taking into account the latest scientific advances in physical, chemical and biological monitoring, many of which have evolved as a consequence of major oil spill disasters in the last decade. It includes sections on the chemical properties of oil, the toxicological impacts of oil exposure, and the impacts of oil exposure on different marine habitats with relevance to Australia and elsewhere. An overview is provided on how monitoring integrates with the oil spill response process, the response organisation, the use of decision-support tools such as net environmental benefit analysis, and some of the most commonly used response technologies. Throughout the text, examples are given of lessons learned from previous oil spill incidents and responses, both local and international.
General guidance of spill monitoring approaches and technologies is augmented with in-depth discussion on both response phase and post-response phase monitoring design and delivery. Finally, a set of appendices delivers detailed standard operating procedures for practical observation, sample and data collection.
The Oil Spill Monitoring Handbook is essential reading for scientists within the oil industry and environmental and government agencies; individuals with responder roles in industry and government; environmental and ecological monitoring agencies and consultants; and members of the maritime sector in Australia and abroad, including officers in ports, shipping and terminals.
Book chapters on the topic "Leukaemia in the Australian petroleum industry"
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Hutchison, Charles S. "The Geological Framework." In The Physical Geography of Southeast Asia. Oxford University Press, 2005. http://dx.doi.org/10.1093/oso/9780199248025.003.0011.
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This chapter outlines the principal geological features of the region, extending from Myanmar and Taiwan in the north, southwards to include all the ASEAN countries, and extending as far as northern Australia. The present-day lithospheric plates and plate margins are described, and the Cenozoic evolution of the region discussed. Within a general framework of convergent plate tectonics, Southeast Asia is also characterized by important extensional tectonics, resulting in the world’s greatest concentration of deep-water marginal basins and Cenozoic sedimentary basins, which have become the focus of the petroleum industry. The pre-Cenozoic geology is too complex for an adequate analysis in this chapter and the reader is referred to Hutchison (1989) for further details. A chronological account summarizing the major geological changes in Southeast Asia is given in Figure 1.2. The main geographical features of the region were established in the Triassic, when the large lithospheric plate of Sinoburmalaya (also known as Sibumasu), which had earlier rifted from the Australian part of Gondwanaland, and collided with and became sutured onto South China and Indochina, together named Cathaysia. The result was a great mountain-building event known as the Indosinian orogeny. Major granites were emplaced during this orogeny, with which the tin and tungsten mineral deposits were genetically related. The orogeny resulted in general uplift and the formation of major new landmasses, which have predominantly persisted as the present-day regional physical geography of Southeast Asia. The Indo-Australian Plate is converging at an average rate of 70 mm a−1 in a 003° direction, pushed from the active South Indian Ocean spreading axis. For the most part it is composed of the Indian Ocean, formed of oceanic sea-floor basalt overlain by deep water. It forms a convergent plate margin with the continental Eurasian Plate, beneath which it subducts at the Sunda or Java Trench. The Eurasian continental plate protrudes as a peninsular extension (Sundaland) southwards as far as Singapore, continuing beneath the shallow Straits of Malacca and the Sunda Shelf as the island of Sumatra and the northwestern part of Borneo.
Conference papers on the topic "Leukaemia in the Australian petroleum industry"
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Cobby, Graham L. "Developing New Environmental Regulations for the Australian Offshore Petroleum Industry." In SPE International Conference on Health, Safety and Environment in Oil and Gas Exploration and Production. Society of Petroleum Engineers, 2000. http://dx.doi.org/10.2118/61008-ms.
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Khatib, Abdel Rahman, Anshuman Mallya, Bowen Dai, and Roberto Costa. "Case Study: Turbine Load-Sharing and Load-Shedding System Foran Australian LNG Facility." In 2019 IEEE Petroleum and Chemical Industry Committee Conference (PCIC). IEEE, 2019. http://dx.doi.org/10.1109/pcic30934.2019.9074511.
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Tantala, Steve. "Stakeholder Consultation and Environmental Implications for the Offshore Petroleum Industry: An Australian Perspective." In SPE International Conference on Health, Safety, and Environment in Oil and Gas Exploration and Production. Society of Petroleum Engineers, 2004. http://dx.doi.org/10.2118/86618-ms.
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Tantala, Steve. "Stakeholder Consultation and Environmental Implications for the Offshore Petroleum Industry: An Australian Perspective (Portuguese)." In SPE International Conference on Health, Safety, and Environment in Oil and Gas Exploration and Production. Society of Petroleum Engineers, 2004. http://dx.doi.org/10.2118/86618-port.
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Parker, Rob, and Nick Parkhurst. "Perth, Western Australia Regional Headquarters for Companies Servicing The Australian and South East Asian Petroleum Industry." In Offshore Technology Conference. Offshore Technology Conference, 1998. http://dx.doi.org/10.4043/8634-ms.
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Harvey, Chris. "Achieving and Demonstrating Pipeline Engineering Capability: The Role of Competency Standards, and Their Use for Qualifications and Registration." In 2018 12th International Pipeline Conference. American Society of Mechanical Engineers, 2018. http://dx.doi.org/10.1115/ipc2018-78321.
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There is increasing pressure on the pipeline industry to be able to demonstrate that its asset management and engineering capability management are at a satisfactory level. This is needed to give policymakers, regulators and industry stakeholders confidence in the safety and environmental sustainability of petroleum pipelines. Regulators, in particular, are seeking assurance from pipeline owner/operators that they have capable pipeline engineers designing, constructing, operating and maintaining petroleum pipelines. At present, there are no generally accepted approaches to recognising and developing pipeline engineering capability. The paper will discuss three levels of capability recognition as: (1) registration – as pipeline engineers (not just in mechanical, civil or chemical engineers (overall standing level)) – (2) qualification (sub-discipline/job level) and (3) competency (task level). The most granular and useful of these is competency. This is because it is at the level that is most immediate: the task at hand. Competency, the combination of knowledge and experience that leads to expertise, is increasingly seen as the best practice basis for learning, particularly for professionals. Significantly, once competencies have been defined in competency standards, they can become the building blocks used to define the requirements for both registration and qualification. The Australian Pipelines and Gas Association (APGA) has developed a comprehensive competency system for both onshore and offshore sectors. There are 226 onshore competency standards and 57 offshore competency standards describing, in a succinct format, what is required to be competent. The succinct format of the competency standards avoids the pitfalls of many other systems of competency description, providing enough information to be clear about what is required without unnecessary complexity. In addition to the detailed competency standards, the competency system has tools, resources and a progressive rating scale that make competency standards accessible and easily used. The competency system is characterised by such flexibility that, to date, APGA has identified 15 applications, all of which will add value to engineers and the companies that employ them. The paper will explain, in detail, APGA’s Pipeline Engineer Competency System, how it works and how it can provide the building blocks for a wide range of tasks that support the training, development and recognition of pipeline engineers’ capabilities, including defining the requirements for registration and qualification. The paper will provide case studies, based on the APGA Competency System, showing how it can be used to create requirements for qualifications and registration and to design in-house training and development plans.
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Prueter, Phillip E., and Brian Macejko. "Establishing Recommended Guidance for Local Post Weld Heat Treatment Configurations Based on Thermal-Mechanical Finite Element Analysis." In ASME 2016 Pressure Vessels and Piping Conference. American Society of Mechanical Engineers, 2016. http://dx.doi.org/10.1115/pvp2016-63581.
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Post weld heat treatment (PWHT) is an effective way to minimize weld residual stresses in pressure vessels and piping equipment. PWHT is required for carbon steels above a Code-defined thickness threshold and other low-alloy steels to mitigate the propensity for crack initiation and ultimately, brittle fracture. Additionally, PWHT is often employed to mitigate stress corrosion cracking due to environmental conditions. Performing local PWHT following component repairs or alterations is often more practical and cost effective than heat treating an entire vessel or a large portion of the pressure boundary. In particular, spot or bulls eye configurations are often employed in industry to perform PWHT following local weld repairs to regions of the pressure boundary. Both the ASME Boiler and Pressure Vessel (B&PV) Code and the National Board Inspection Code (NBIC) permit the use of local PWHT around nozzles or other pressure boundary repairs or alterations. Additionally, Welding Research Council (WRC) Bulletin 452 [1] offers detailed guidance relating to local PWHT and compares some of the Code-based methodologies for implementing local PWHT on pressure retaining equipment. Specifically, local PWHT methodologies provided in design Codes: ASME Section VIII Division 1 [2] and Division 2 [3], ASME Section III Subsection NB [4], British Standard 5500 [5], Australian Standard 1210 [6], and repair Codes: American Petroleum Institute (API) 510 [7] and NBIC [8] are discussed and compared in this study. While spot PWHT may be appropriate in certain cases, if the soak, heating, and gradient control bands are not properly sized and positioned, it can lead to permanent vessel distortion or detrimental residual stresses that can increase the likelihood of in-service crack initiation and possible catastrophic failure due to unstable flaw propagation. It is essential to properly engineer local or spot PWHT configurations to ensure that distortion, cracking of adjacent welds, and severe residual stresses are avoided. In some cases, this may require advanced thermal-mechanical finite element analysis (FEA) to simulate the local PWHT process and to predict the ensuing residual stress state of the repaired area. This paper investigates several case studies of local PWHT configurations where advanced, three-dimensional FEA is used to simulate the thermal-mechanical response of the repaired region on a pressure vessel and to optimize the most ideal PWHT arrangement. Local plasticity and distortion are quantified using advanced non-linear elastic-plastic analysis. Commentary on the ASME and NBIC Code-specified local PWHT requirements is rendered based on the detailed non-linear FEA results, and recommended good practice for typical local PWHT configurations is provided. Advanced computational simulation techniques such as the ones employed in this investigation offer a means for analysts to ensure that local PWHT configurations implemented following equipment repairs will not lead to costly additional damage, such as distortion or cracking that can ultimately prolong equipment downtime.