Modeling the characteristics of a bottom trawl

The purpose of the work is to create software for calculating the structural, geometric and strength characteristics of mesh bottom trawl structures, intended for modeling technological and hydrodynamic processes of trawl structures.

Methods used: The software “Calculation of the structural, technological and power characteristics of a bottom mesh trawl” is written in C++ in the Embarcadero RAD Studio software development environment and is designed to run on the Microsoft Windows 10 operating system.

Novelty: based on the results of experimental studies, mathematical and simulation models of the mechanics of trawl structures were analyzed for the first time and software was developed that allows calculating the characteristics of mesh trawl structures, including material costs for the manufacture of trawl structures.

Result: The software displays the static process of trawling a mesh bottom trawl, as well as the output technological (for the technologist), geometric and power (for the designer) characteristics.

Practical significance: the developed software is expected to be used in the future as a simulator module for training aquatic organisms getters, trawl masters and assistant captains for production.

1. Afanasiev V.O. 2007. Systems of 3D visualization of the induced virtual environment. Abstr. of the disser. doctor of Sciences in Phys.-Math. Moscow: MSU. 36 p. (In Russ.)

2. Bidenko G. E. 1971. Soil mechanics. Sat. Proceedings of AtlantNIRO. Iss. 50. P. 33–54. (In Russ.)

3. Boreskov A.V. 2006. Development and debugging of shaders. St. Petersburg: BHV-Petersburg. 173 p. (In Russ.)

4. Vadyunina A.F., Kortchagina Z.A. 1986. Methods for studying the physical properties of soil. Moscow: Agropromizdat. 416 p. (In Russ.)

5. Vedeneev V. L. 1975. Methodology for taking into account the influence of soil on the operation of trawl doors // Industrial fishing: Express information NIITEIRH. Iss. 5. 20 p. (In Russ.)

6. Evchenko A. I. 2006. OpenGL and DirectX // Graphics Programming. SPb.: Peter Publishing. 350 p. (In Russ.)

7. Korotkov V.K. 1972. Trawl, the behavior of the object of fishing and underwater observations of them. Moscow: Food industry. 271 p. (In Russ.)

8. Korotkov V.K. 1998. The reaction of fish to the trawl, the technology of their fishing. Kaliningrad: SEDD JSC «MARINPO». 397 p. (In Russ.)

9. Mizyurkin M.A. 2012. Influence of the angle of attack of trawl doors on the drag and geometrical parameters of the bottom trawl system // News of KSTU. No. 24. P. 158–165. (In Russ.)

10. Nedostup A. A., Razhev A.O. 2017. Mathematical model of the interaction of a spacer trawl door with the aquatic environment // Marine intellectual technologies. No. 3 (37) V.1. P. 154–157. (In Russ.)

11. Nedostup A.A., Razhev A.O. 2021. Productivity of the forces of the trawl system: Statement of the problem // Bulletin of the Astrakhan STU. Series: Fisheries. No. 2. P. 55–65. (In Russ.)

12. Nedostup A.A., Razhev A.O. 2022. A criterion characterizing the degree of impact of a trawl door on the benthos of a water body // Coll. of papers mat. of the 49 intern. scient. and pract. conf. «Issues of technical and physical and mathematical sciences in the light of modern research.» Novosibirsk: Siberian Academy of Books. P. 26–30. (In Russ.)

13. Oberg R. J. 2000. COM+ technology. Fundamentals and programming. Moscow: Williams Publishing. (Oberg R.J. 1999. Understanding & programming COM+ a practical guide to Windows 2000 DNA. Prentice Hall PTR). 480 p. (In Russ.)

14. Salibekyan S.M., Panfilov P.B. 2011. Construction of distributed heterogeneous computing systems based on objectattribute architecture // Object systems. No. 5(5). P. 83–88. (In Russ.)

15. Stroustrup B. 2019. The C++ Programming Language. Short course. 2nd ed. Sankt-Petersburg: OOO «Dialektika» (Stroustrup B. A Tour of C++. Boston et al.: Addison Wesley). 320 p. (In Russ.).

16. Fryer R.J., Summerbell K., O’Neill F.G. 2017. A meta-analysis of vertical stratification in demersal trawl gears // Canadian J. of Fisheries and Aquatic Sciences. 74(8). Р. 1243–1250.

17. Hunter D., Rafter J., Fawcett J., Vlist E., Ayers D., Duckett J., Watt A., McKinnon L. 2007. Beginning XML. 4th Edition. Wiley Publishing, Inc. 1080 р.

18. LaViola Jr., Е. Kruijff, R. McMahan, D. Bowman, Poupyrev I. 2017. 3D User Interfaces. Theory and Practice. Second Edition. Addison-Wesley. 507 p.

19. O’Neill, F.G., Summerbell, K., Ivanović, A. 2018. The contact drag of towed demersal fishing gear components // J. of Marine Systems. V. 177. Р. 39–52.

20. Rijnsdorp, A.D., Depestele, J., Eigaard, O.R., Hintzen, N.T., Ivanovic, A., Molenaar, P., O’Neill, F., Polet, H., Poos, J.J., van Kooten, T. 2020. Mitigating seafloor disturbance of bottom trawl fisheries for North Sea sole Solea solea by replacing mechanical with electrical stimulation // PLoS One. V. 15. No 11. P. e0228528.

21. Rijnsdorp, A.D., Depestele, J., Molenaar, P., Eigaard, O.R., Ivanović, A., O’Neill, F.G. 2021. Sediment mobilization by bottom trawls: a model approach applied to the Dutch North Sea beam trawl fishery // ICES J. of Marine Science. 78(5). Р. 1574–1586.

22. Varcholik P. 2014. Real-Time 3D Rendering with DirectX and HLSL: A Practical Guide to Graphics Programming. Addison-Wesley Professional. 592 p.