Heat Loss of Heated Deck Elements in Cross-Flow Wind

2017 ◽  
Author(s):  
Jino Peechanatt ◽  
Bjarte O. Kvamme ◽  
Ove T. Gudmestad ◽  
Yaaseen A. Amith
Keyword(s):  
Power Consumption ◽  
Heat Loss ◽  
Oil And Gas ◽  
Cross Flow ◽  
Arctic Region ◽  
Coast Guard ◽  
The Arctic ◽  
Efficient Design ◽  
Oil And Gas Exploration ◽  
Polar Code

In recent years, there has been unprecedented interest shown in the Arctic region by the industry, as it has become increasingly accessible for oil and gas exploration, shipping, and tourism. The decrease in ice extent in the Arctic has renewed the interest in the Northern Sea route, necessitating further research to evaluate the adequacy of the equipment and appliances used on vessels traversing in polar waters. The introduction of the Polar Code by the International Maritime Organization (IMO) attempts to mitigate some of the risks endangering the vessels in Polar waters. The Polar Code is scheduled to take effect on 01.01.2017, and applies to all vessels traversing in polar waters. One of the requirements in the Polar Code is that means shall be provided to remove or prevent accretion of snow and/or ice from escape routes, embarkation areas and access points. Even though, prior to the formulation of Polar Code, the requirement for de-icing the deck surfaces on vessels already exists, the suitability of the equipment currently in use is debatable. Large amounts of energy is required to maintain an ice-free surface, which is not desirable economically or environmentally, due to the substantial increase in fuel consumption. In this study, a heated deck element manufactured by GMC Maritime AS is subjected to cross flow wind of 5 m/s, 10 m/s and 15 m/s at various sub-zero temperatures in GMC Maritime AS’s climate laboratory in Stavanger, Norway. The deck element is rated to 1400 W / m2, and is one of the designs provided by GMC Maritime AS. The power consumption of the deck element is measured and compared to theoretical heat loss calculations. Large discrepancies between the measured power consumption and the theoretical heat loss were discovered, indicating the need for further studies on the matter. As part of SARex Spitzbergen 2016, a search and rescue exercise conducted off North Spitzbergen, heated deck elements on board the Norwegian Coast Guard Vessel KV Svalbard were studied and are discussed in this paper. The heating elements in the deck elements were designed to specifications at the time of commissioning, but proves insufficient when the vessel is in transit or exposed to slight winds, allowing snow and ice to accumulate on the surface. Finally, suggestions for a more energy efficient design of deck elements are made, as the current designs are found to have potential for improvement, especially due to the lack of insulation between the deck elements and the hull of the vessel.

Heat Loss of Insulated Pipes in Cross-Flow Winds

2018 ◽  
Vol 141 (2) ◽  
Author(s):  
Bjarte O. Kvamme ◽  
Jino Peechanatt ◽  
Ove T. Gudmestad ◽  
Knut E. Solberg ◽  
Yaaseen A. Amith
Keyword(s):  
Heat Transfer ◽  
Oil And Gas ◽  
Theoretical Calculations ◽  
Cross Flow ◽  
Arctic Region ◽  
The Arctic ◽  
Transfer Coefficients ◽  
Oil And Gas Exploration ◽  
Heat Transfer Coefficients ◽  
Single Pipe

In recent years, there has been unprecedented interest shown in the Arctic region by the industry as it has become increasingly accessible for oil and gas exploration. This paper reviews existing literature on heat transfer coefficients and presents a comprehensive study of the heat transfer phenomenon in horizontal pipes (single/multiple pipe configurations) subjected to cross-flow wind besides the test methodology used to determine heat transfer coefficients through experiments. In this study, cross-flow winds of 5 m/s, 10 m/s, and 15 m/s blowing over several single pipe and multiple pipe configurations of diameter 25 mm and 50 mm steel pipes with insulation are examined. Based on the findings, the best correlation for use by the industry for single and multiple pipe configurations was found to be Churchill–Bernstein correlation. The deviation from the theoretical calculations and the experimental data for this correlation was found to be in the range of 0.40–1.61% for a 50 mm insulated pipe and −3.86% to −2.79% for a 25 mm insulated pipe. In the case of a multiple pipe configurations, the deviation was in the range 0.5–2.82% for 50 mm insulated pipe and 12–14% for 25 mm insulated pipes.

Calculation of Time-to-Freeze for Liquids in Pipes

2017 ◽  
Author(s):  
Bjarte O. Kvamme ◽  
Jino Peechanatt ◽  
Ove T. Gudmestad
Keyword(s):  
Oil And Gas ◽  
Temperature Drop ◽  
Arctic Region ◽  
Oil And Gas Industry ◽  
Cold Climate ◽  
The Arctic ◽  
Flow Assurance ◽  
Maritime Industry ◽  
Oil And Gas Exploration ◽  
Polar Code

In recent years, there has been unprecedented interest shown in the Arctic region by the industry, as it has become increasingly accessible for oil and gas exploration, shipping, and tourism. The decrease in ice extent in the Arctic has renewed the interest in the Northern Sea route, necessitating further research to evaluate the adequacy of the equipment and appliances used on vessels traversing in polar waters. In the oil and gas industry, exploration and production vessels and platforms are highly dependent on the piping facilities for rendering their intended function, and therefore, flow assurance is extremely crucial. If the winterization of pipes is not done properly, this could lead to massive cost overruns due to unplanned production shutdowns or even worse, accidents. A temperature drop between the different areas of the production facilities will change the thermodynamic properties of the fluids, and could cause the processing of the crude oil to become inefficient. The introduction of the Polar Code by the International Maritime Organization (IMO) attempts to mitigate some of the risks endangering the vessels in polar waters. The Polar Code is scheduled to take effect on 01.01.2017, and applies to all vessels traversing in polar waters. The Polar Code requires that all machinery installations and associated equipment required for the safe operation of ships shall be protected against the effect of freezing and increased viscosity of liquids, and that working liquids shall be maintained in a viscosity range that ensures the operation of the machinery. To account for this, the heat loss of pipes carrying liquid (water for fire extinguishing and hydraulic fluid amongst others) needs to be estimated and mitigating measures must be taken. In this study, methodology from the refrigeration industry is applied to calculate the estimated time to freeze for liquids in pipes. The methodology is adapted for use in the maritime industry, and results are presented in this study. The methodology used was found to be quite flexible, allowing for the calculation of complex scenarios and shapes, including the effect of varying degrees of insulation on pipes, and can easily be applied for approximating the best suitable method of insulating pipes to ensure flow assurance and maintain fluid properties at desired levels. Tables estimating the time-to-freeze for insulated pipes of different diameters and insulation thicknesses exposed to cross-winds of varying speeds are provided. The methodology is found to have great potential, and should be investigated further with experiments. The objective of the paper is thus to introduce the methodology for cold-climate engineering and use it for practical analysis of realistic estimates of insulated and non-insulated piping.

Application of De-Icing Techniques for Arctic Offshore Production Facilities

2014 ◽  
Author(s):  
Rezgar Zaki ◽  
Abbas Barabadi
Keyword(s):  
Life Cycle Cost ◽  
Energy Demand ◽  
Oil And Gas ◽  
Arctic Region ◽  
Oil And Gas Industry ◽  
The Arctic ◽  
Operational Conditions ◽  
Oil And Gas Exploration ◽  
Offshore Production ◽  
Production Facilities

With increasing energy demand, the oil and gas industry is pushing towards new unexplored remote Arctic areas. More than 25% of undiscovered petroleum reserves are expected to be in the Arctic region. Moreover, it is estimated that approximately 84% of the undiscovered oil and gas occurs offshore. There are numerous challenges and environmental factors that must be overcome before one can conduct oil and gas exploration, and engage production activities in Arctic regions. Superstructure icing from sea spray and atmospheric icing affect operation and maintenance of offshore production facilities in various ways including repair time, failure rate of mechanical and electrical components, power losses, life cycle cost, and safety hazard and can cause downtime in the facilities. These problems are motivating designers, manufacturers and safety researchers to find better practical solutions for ice protection technologies. Many active and passive anti-icing and de-icing techniques have been used in different industries such as electric power. However, Arctic offshore operational conditions provide new challenges for application of these methods and they have limitation of usage due to harsh and sensitive environment and wilderness, lack of infrastructure as well as distance to the market. Hence, such conditions must be considered during design and operation phase for anti-icing and de-icing techniques. This paper discusses how operational conditions of Arctic region can affect the application of available anti-icing and de-icing techniques. Moreover, it will discuss different types of ice accretion and their hazard for the Arctic offshore production facilities.

Sustainable Development of Oil Production in the Arctic Shelf and Evolution of Fish Stock

2019 ◽  
pp. 451-469
Author(s):  
Yuri Yegorov
Keyword(s):  
Sustainable Development ◽  
Oil And Gas ◽  
Barents Sea ◽  
Arctic Region ◽  
Renewable Resource ◽  
Academic Community ◽  
The Arctic ◽  
Fish Stock ◽  
Common Pool ◽  
Arctic Fish

Arctic region is an important resource for hydrocarbons (oil and gas). Their exploitation is not immediate but will develop fast as soon as oil prices approach $100 per barrel again. In the Arctic, fish stock is an important renewable resource. Contrary to hydrocarbons, it is already overexploited. Future simultaneous exploitation of both resources poses several problems, including externalities and common pool. The academic community still has some time for theoretical investigation of those future problems and working out the corresponding policy measures that are consistent with sustainable development of the region. The Barents Sea is especially important because it has a common pool both in hydrocarbons and fish.

scholarly journals Forecasting of Technology Development of the Arctic Hydrocarbon Resources’ Extraction

2020 ◽  
Vol 162 ◽  
pp. 01008
Author(s):  
Tatiana Chvileva
Keyword(s):  
Oil And Gas ◽  
Technology Development ◽  
Arctic Region ◽  
Oil And Gas Industry ◽  
Integrated Approach ◽  
The Arctic ◽  
Gas Industry ◽  
Industrial Systems ◽  
Technological Forecasting ◽  
Energy Needs

The Arctic region has a great potential in development of hydrocarbon resources and can play an important role in meeting future global energy needs. In the presented work the specific features of the Arctic hydrocarbon projects are identified. Key needs of oil and gas industry in technology development within the framework of projects of extraction of hydrocarbon resources in the Arctic are revealed. A critical analysis of technological forecasting methods is presented. Problems and prospects of their use in the conditions of the Arctic zones are established. The need for an integrated approach to forecasting the development of industrial systems of the Arctic zone is justified.

Floaters for Oil and Gas Exploration in the Arctic - A Review

2016 ◽  
Author(s):  
Aziz Ahmed ◽  
Xudong Qian ◽  
Benjamin Xia Tian Peng ◽  
Zhuo Chen ◽  
Ankit Choudhary ◽  
...  
Keyword(s):  
Oil And Gas ◽  
The Arctic ◽  
Oil And Gas Exploration

In Situ Oil Spill Countermeasures in Ice-Infested Waters: A Modeling Study of the Fate/Behaviours of Spilled Oil

2014 ◽  
Vol 2014 (1) ◽  
pp. 1215-1225 ◽  
Author(s):  
Haibo Niu ◽  
Kenneth Lee ◽  
Michel C. Boufadel ◽  
Lin Zhao ◽  
Brian Robinson
Keyword(s):  
Oil Spill ◽  
Oil And Gas ◽  
Arctic Region ◽  
The Arctic ◽  
Oil Transport ◽  
Habitat Recovery ◽  
Dispersed Oil ◽  
Oil Biodegradation ◽  
Arctic Conditions ◽  
Spilled Oil

ABSTRACT The expansion of offshore oil and gas and marine transport activities in the Arctic have raised the level of risk for an oil spill to occur in the Arctic region. Existing technologies for oil spill cleanup in ice-covered conditions are limited and there is a need for improved oil spill countermeasures for use under Arctic conditions. A recent field study has assessed a proposed oil spill response technique in ice-infested waters based on the application of fine minerals in a slurry with mixing by propeller-wash to promote the formation of oil-mineral aggregates (OMA). While it was verified in the experimental study that the dispersion was enhanced and mineral fine additions promoted habitat recovery by enhancing both the rate and extent of oil biodegradation, limited monitoring data provide little insights on the fate of dispersed oil after the response. To help understand the oil transport process following mineral treatment in ice-covered conditions, mathematical modeling was used in this study to simulate the transport of OMA and calculate the mass balances of the spilled oil. To study the effects of ice and minerals on the fate and transport, the result was compared with scenarios without ice and without the addition of mineral fines. The results show general agreement between the modeling results and field observations, and further confirm the effectiveness and potential for using mineral treatment as a new oil spill counter-measure technology. This technique offers several operational advantages for use under Arctic conditions, including reduced number of personnel required for its application, lack of need for waste disposal sites, and cost effectiveness.

Three years (2017-19) of field observation of the marginal ice the Western Barents Sea

2020 ◽  
Author(s):  
Nataliya Marchenko
Keyword(s):  
Sea Ice ◽  
Laser Scanning ◽  
Oil And Gas ◽  
Barents Sea ◽  
Mechanical Tests ◽  
Point Of View ◽  
The Arctic ◽  
Oil And Gas Exploration ◽  
Ice Floes ◽  
The University

<p>Knowledge of sea ice state (distribution, characteristics and movement) is interesting both from a practical point of view and for fundamental science. The western part of the Barents Sea is a region of increasing activity – oil and gas exploration may growth in addition to traditional fishing and transport. So theinformation is requested by industry and safety authorities.</p><p>Three last years (2017-19) the Arctic Technology Department of the University Centre in Svalbard (UNIS) performed expeditions on MS Polarsyssel in April in the sea ice-marginal zone of the Western Barents Sea, as a part of teaching and research program. In (Marchenko 2018), sea ice maps were compared with observed conditions. The distinguishing feature of ice in this region is the existence of relatively small ice floes (15-30 m wide) up to 5 m in thickness, containing consolidated ice ridges. In (Marchenko 2019) we described several such floes investigated by drilling, laser scanning and ice mechanical tests, on a testing station in the place with very shallow water (20 m) where ice concentrated. In this article, we summarise three years results with more attention for level ice floes and ice floe composition, continuing to feature ice condition in comparison with sea ice maps and satellite images.</p><p>These investigations provided a realistic characterization of sea ice in the region and are a valuable addition to the long-term studies of sea ice in the region performed by various institutions.</p>

Spatial Organization of Economic Development of Energy Resources in the Arctic Region of the Russian Federation

2018 ◽  
Vol 9 (3) ◽  
pp. 605 ◽  
Author(s):  
Sergey Anatolievich AGARKOV ◽  
Sergey Yurievich KOZMENKO ◽  
Anton Nikolaevich SAVELIEV ◽  
Mikhail Vasilyevich ULCHENKO ◽  
Asya Aleksandrovna SHCHEGOLKOVA
Keyword(s):  
Economic Development ◽  
Spatial Organization ◽  
Oil And Gas ◽  
Arctic Region ◽  
The Arctic ◽  
World Energy ◽  
The Russian Federation ◽  
D Model ◽  
Gas Bearing ◽  
The Arctic Region

In the conditions of price reduction in the world energy market, the issue of determining the priorities of the economic development of hydrocarbons in the Arctic Region of the Russian Federation (RF) becomes highly relevant. The article is aimed at developing an optimal model for the spatial organization of energy resources in the Arctic Region. The expert elicitation procedure was used to determine the efficiency indicators for the economic development of the oil-and-gas-bearing areas in the Arctic Region and clusterization of these areas was carried out in terms of economic efficiency. Based on the factor analysis, the degree of influence of efficiency indicators on the economic development of the oil and gas bearing areas of the region was determined and, an integrated performance indicator of economic development for oil-and-gas-bearing areas for each cluster was calculated with regard to the factor loadings. A 3-D model was developed for the organization of economic development of oil and gas in the Arctic Region. The 3-D model became the basis for determining the priorities for territorial exploration, development and production of hydrocarbons in terms of their economic efficiency, taking into account the trends in the development of the world energy market and break-even fields. A set of recommendations was developed to improve the efficiency of the spatial organization of economic development of oil and gas in the Arctic Region. The implementation of the proposed measures can contribute to the development of the oil and gas industry in the region, its socio-economic development and the long-term sustainability of Russia's energy security.

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