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Published: Tuesday, 18 April 2023 18:52
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Volume 14 (2), April 2023, Pages 47-52
Elshan Jafarov1, Lala Aliyeva2
1Chief mechanic, “Turan Drilling & Engineering”. Department of Materials Science and Processing Technologies, Faculty of Petroleum Mechanics, Azerbaijan State Oil and Industry University, Azerbaijan. E-mail: This email address is being protected from spambots. You need JavaScript enabled to view it.
2Training master, department of “Industrial Machines”, Azerbaijan State Oil and Industry University, Azerbaijan.
ABSTRACT
Continuous casting is essentially the youngest and most dynamically developing technology in the steel production and casting system as an industrial method of shaped casting process. At present, continuous casting of steel is adopted in more than 90 countries of the world. About 2,000 continuous casting machines (CCMs) of different purposes and designs are now in good operation, which allow casting about 93% of all steel produced in the world. At this time, steel bars with the following maximum cross-sections are produced in the industry: blue 600×670mm, slab 250×3200mm and circular bars with a diameter of 600mm. In many developed countries of the world, almost 95-100% of steel production is produced by continuous casting. is being for example, in 2018, 1.228 billion tons of steel were produced by continuous casting in the world, which is a record in the history of metal production. as a result of experimental studies, proposals were developed for the application of important technologies in the development of non-furnace processing of liquid metal and continuous casting in the Republic.
Keywords: Steel making, permanent casting devices, construction, vacuuming, liquid metal, intermediate heat, temperature, impact viscosity, electrometallurgy.
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Category: Uncategorised
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Published: Tuesday, 18 April 2023 18:48
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Volume 14 (2), April 2023, Pages 29-38
Amir Mustafayev1, Chingiz Nasirov2
1Associate Professor, Department of Mechanics, Azerbaijan State Oil and Industry University, Azerbaijan. Email: This email address is being protected from spambots. You need JavaScript enabled to view it.
2Master, Department of Transportation and Storage of Oil and Gas, Azerbaijan State Oil and Industry University, Azerbaijan. Email: This email address is being protected from spambots. You need JavaScript enabled to view it.
ABSTRACT
The maintenance of equipment and tools used in the workover of oil and gas wells depends on keeping them in working condition, reliability, strength and temperature endurance of the tool.
In order to restore wells in case of an accident and bring them back into operation, it is necessary to speed up the drilling and repair work by choosing the right repair equipment and following the existing rules and regulatory documents.
The cutting elements of the tools working under high pressure and loads are deformed, a tense situation is created in the cutting – destruction zone, high temperatures (10000 - 12000) occur as a result of corrosion in the triboknots.
The stress-deformation state in the cutting-destruction zone causes the formation of microcracks in the working area of the tool. Microcracks grow after a certain period of time. Cutting elements are quickly worn, in some cases broken and fail quickly. Such cases affect the structural composition of the cutting elements, the temperatures increase, as a result, riveting occurs.
In order to keep the equipment and tools used in the repair in normal working condition, adjusting the mode parameters is one of the important requirements, in addition to taking special care of them. The high results obtained in repair and restoration works depend on the efficiency of the cutting-destructive tool, longevity, material selection, construction manufacturing technologies, tool that meet modern requirements, dimensions, weight and internal condition of the well being restored.
It is necessary to keep the heat generated in the moving parts of the tool at the required level for the safe performance of restoration works.
The thermal regime of cutting and rock-destroying tools depends on the physical-mechanical properties of the objects subjected to destruction and the effect of thermomechanical stresses generated on the contact surfaces of the tool and the amount of heat released from the working surface.
Studying the problems related to heat issues will allow to ensure the temperature tolerance of not only the repair equipment, but also the equipment and tools used in other areas of the oil-field industry.
Keywords: temperature, cutting and destructive tool, metal, rock.