Nikiforov
Vladimir O.
D.Sc., Prof.
doi: 10.17586/2226-1494-2016-16-4-738-744
COMPUTER SIMULATION OF ELECTROMAGNETIC LOG SENSOR STRENGTH CHARACTERISTICS
Read the full article
';
For citation: Avanesov Y.L., Voronov A.S., Evstifeev M.I. Computer simulation of electromagnetic log sensor strength characteristics. Scientific and Technical Journal of Information Technologies, Mechanics and Optics, 2016, vol. 16, no. 4, pp. 738–744. doi: 10.17586/2226-1494-2016-16-4-738-744
Abstract
Subject of Research.The problems of insufficient strength of the EM log sensor are studied. The EM log sensor design for deep-sea vehicles is analyzed; a mathematical model of EM log sensor is built. The design and technological solutions that improve the performance of this type of log are shown. Method. The study was performed using the finite element method in the ANSYS software. The calculations were performed in the static structural module, in which the load was created in the way that simulated the external hydrostatic pressure. To check the reproducibility the analysis of model was carried out by built-in assessment of the quality elements. All materials are taken to be isotropic. Main Results. The ways of increasing the strength of outboard tools for measuring the ship speed are presented. Calculating results of the stress-strain state of devices under the influence of seawater at various depths were obtained by the method of finite element analysis. The technological features of the sensor production are shown. The recommendations for changing the log construction to increase its strength, supported by computer modeling, are given. Practical Relevance. The discussed ways of increasing the strength of the device enable to expand implementation area. The results can be applied in the modernization of the design and construction of new EM log sensor operating at high pressures.
References
1. Burilichev A.V. Future of humanity is inextricably linked with the study, research the ocean. Bezopasnost' Rossii, 2011, no. 5, pp. 40–43. (In Russian)
2. Sagalevich A.M. Manned submersible IO RAS. Materialy XIV Mezhdunarodnoi Nauchno-Tekhnicheskoi Konferentsii Sovremennye Metody i Sredstva Okeanicheskikh Issledovanii. Moscow, 2015, vol. 2, pp. 14–30.
3. Andreev S.I. Mineral resources of the World Ocean: prospects for exploration and development. In Geologiya Morei i Okeanov. Moscow, 2007, pp. 85–87.
4. Filimonov A.K. Underwater robotics. Materialy Mezhdunarodnoi Nauchno-Tekhnicheskoi Konferentsii «Ekstremal'naya Robototekhnika» [Proc. Int. Sci.-Tech. Conf. on Extreme Robotics]. St. Petersburg, Russia, 2011, pp. 43–49. (In Russian)
5. Grishchenko N. Apparatus "Rus’" Sank to the Transcendent Depth. Available at: http://rg.ru/2015/12/14/rus-site-anons.html (accessed 25.06.2016).
6. Lisitsyn A.P. Columbuses of ocean depths. Herald of the Russian Academy of Sciences, 2003, vol. 73, no. 9, pp. 842–848. (In Russian)
7. Konyukhov F. Russian project dive into the Mariana Trench of the Pacific Ocean. Available at: http://konyukhov.ru/projects/expedition/rossijskij-proekt-pogruzheniya-v-marianskuyu-vpadinu-tixogo-okeana.html (accessed 25.06.2016).
8. Rossiiskii Morskoi Registr Sudokhodstva [Russian Maritime Register of Shipping].
9. Saranchin A.I., Polkovnikov V.F., Zav'yalov V.V. Inductive Electronic Log IEL-2M. Vladivostok, 2003, 40 p. (In Russian)
10. Dmitriev S.P., Zinenko V.M., Litvinenko Yu.A. Correction and damping of medium accuracy INS using electromagnetic log. Gyroscopy and Navigation, 2012, vol. 3, no. 4, pp. 270–274. doi: 10.1134/S2075108712040025
11. Joon L., You-Chol L. Transfer alignment considering measurement time delay and ship body flexure. Journal of Mechanical Science and Technology, 2009, vol. 23, no. 1, pp. 195–203. doi: 10.1007/s12206-008-0821-y
12. Li Q., Sun F., Yu F., Gao W. The use of adaptive network-based fuzzy inference system for marine AHRS. Gyroscopy and Navigation, 2014, vol. 5, no. 2, pp. 108–112. doi: 10.1134/S2075108714020059
13. Electromagnetic Log LEM-2M. Available at: http://www.elektropribor.spb.ru/ru/newprod/rekl2014/lag_lem21m.pdf (accessed 25.06.2016).
14. Kute S.Y., Wakchaure M.R. Performance evaluation for enhancement of some of the engineering properties of bamboo as reinforcement in concrete. Journal of The Institution of Engineers (India): Series A, 2013, vol. 94, no. 4, pp. 235–242.
15. Foster S.J. The application of steel-fibres as concrete reinforcement in Australia: from material to structure. Materials and Structures, 2009, vol. 42, no. 9, pp. 1209–1220. doi: 10.1617/s11527-009-9542-7
16. Compounds Based on Epoxy Resins. Available at: http://all-epoxy.ru/tablizi/kompaund.htm (accessed 25.06.2016).
17. Skripnik E.S., Zolotov S.M. Changing wetting with acrylic compound various surfaces. Stroitel'stvo, Materialovedenie, Mashinostroenie [Construction, Materials Science, Mechanical Engineering]. Dnepropetrovsk, PGASA Publ., 2010, p. 5.
18. Abdul-Karem W., Green N., Al-Raheem K.F., Hasan A.H.A. Effect of vibration after filling on mechanical reliability in thin wall investment casting with fillability filling regime – part 1. International Journal of Advanced Manufacturing Technology, 2013, vol. 67, no. 9–12, pp. 2075–2082. doi: 10.1007/s00170-012-4632-z
19. Element Quality. Available at: https://www.sharcnet.ca/Software/Ansys/16.2.3/en-us/help/wb_msh/msh_Element_Quality_Metric.html (accessed 25.06.2016).
20. Pisarenko G.S., Yakovlev A.P., Matveev V.V. Spravochnik po Soprotivleniyu Materialov [Handbook of Materials Strength]. Naukova Dumka Publ., 1975.
