Optimization of Steel Structures Using Cad-Systems

The research is carried out into the possibility of using the computational algorithm for the synthesis of design solutions for steel structures. The dependence between the truss span and the actual load and the optimum height and minimum mass of the truss is described in this paper. Graphical dependences are obtained to show the change in mass and cost of the structure. The dependence is determined between the cost of the structure and the types of steel and section. The suggested algorithm is based on CAD information technology for the industrial steel structural design solutions and implemented as a subsystem of automated design.

автоматизированное проектирование стальных конструкций, оптимальное решение, критерий оптимальности, automated design of steel structures, optimum solution, optimization

1. Gemmerling G.A. Podsistema optimizatsii konstruktsii v SAPR [Optimization subsystem in CAD systems]. Sistema avtomatizirovannogo proektirovaniya stal'nykh stroitel'nykh konstruktsii. Moscow : Stroyizdat Publ., 1987. 216 p. (rus)

2. Turchak L.I. Osnovy chislennykh metodov [Basics of numerical methods]. Moscow : Nauka Publ., 1987. Pp. 169–204. (rus)

3. Kirsanov M.N. Staticheskii raschet i analiz prostranstvennoi sterzhnevoi sistemy [Static calculation and analysis of spatial rod system]. Magazine of Civil Engineering. 2011. No. 6. Pp. 26–34. (rus)

4. Baranovskaya L.V. Ispol'zovanie metoda proektsii gradienta pri optimal'nom proektirovanii metallokonstruktsii tyazhelykh kozlovykh kranov [Gradient projection method used in optimum design of steel structures of heavy gantry cranes]. Vestnik Saratov State Technical University. 2010. V. 1. No. 1. Pp. 24–27. (rus)

5. Kirsanov M.N. Geneticheskii algoritm optimizatsii sterzhnevykh sistem [Genetic algorithm of optimization of bar systems]. Stroit. mekh. i raschet sooruzhenii. 2010. No. 2. Pp. 60–63. (rus)

6. Gladkov V.A., Kureichik V.V., Kureichik V.M. Geneticheskie algoritmy [Genetic algorithms]. Moscow : Fizmatlit Publ., 2006. 320 p. (rus)

7. Rajeev S., Krishnamoorthy C. Genetic algorithms-based methodologies for design optimization of trusses. J. Struct. Eng. 1997. No. 123. Pp. 350–9.

8. Flager F., Adya A., Haymaker J., Fischer M. A bi-level hierarchical method for shape and member sizing optimization of steel truss structures. Computers and Structures. 2014. No. 131. Pp. 1–11.

9. Tusnin A.R. Konechnyi element dlya chislennogo rascheta konstruktsii iz tonkostennykh sterzhnei otkrytogo profilya [Finite element for structural numerical calculation of open section thin-wall bar]. Metal Constructions Journal. 2009. V. 15. No. 1. Pp. 73–78. (rus)

10. Garifullin M.R., Semenov S.A., Belyaeva S.V., Poryvaev I.A., Safiullin M.N., Semenov A.A. Poisk ratsional'noi geometricheskoi skhemy prostranstvennoi metallicheskoi konstruktsii pokrytiya bol'sheproletnogo sportivnogo sooruzheniya [Search for rational spatial geometry of metal coating for large span structure]. Construction of Unique Buildings and Structures. 2014. No. 2. Pp. 107–124. (rus)

11. Lebed' E.V. Komp'yuternoe modelirovanie tochnosti vozvedeniya dvukhpoyasnykh metallicheskikh kupolov [Computer simulation of metal dome design]. J. Industrial and Civil Engineering. 2013. No. 12. Pp. 89–92. (rus)

12. Ginzburg A.V., Vasil'kin A.A. Postanovka zadachi optimal'nogo proektirovanii stal'nykh konstruktsii [The problem of optimum design of steel structures]. Scientific and Technical Journal on Construction and Architecture. 2014. No. 6. Pp. 52–62. (rus)

13. Vasil'kin A.A., Shcherbina S.V. Avtomatizirovannoe reshenie zadachi opredeleniya optimal'noi vysoty stal'noi fermy po kriteriyu minimuma massy pri variatsii vysoty fermy [Automated determination of optimum height of steel truss using minimum weight criterion at truss variation]. Proc. Int. Sci. Conf. ‘Integration, Partnership and Innovations in Construction Science and Education', Moscow : MGSU Publ., 2015. (rus)

14. Vasil'kin A.A., Shcherbina S.V. Postroenie sistemy avtomatizirovannogo proektirovaniya pri optimizatsii stal'nykh stropil'nykh ferm [Computer-aided design in optimization of truss frameы]. Scientific and Technical Journal on Construction and Architecture. 2015. No. 2. Pp. 21–37. (rus)

15. Wu C.Y., Tseng C.Y. Truss structure optimization using adaptive multi-population differential evolution. Structural and Multidisciplinary Optimization. 2010. V. 42. Pp. 351–369.

16. Balling R., Briggs R., Gillman K. Multiple optimum size/shape/topology designs for skeletal structures using a genetic algorithm. ASCE Journal of Structural Engineering. 2006. V. 132. Pp. 1158–1165.

17. Su R., Gui L., Fan Z. Truss topology optimization using genetic algorithm with individual identification technique. Proceedings of the World Congress on Engineering. July 1–3, London, U.K. 2009. V. 2. Pp. 45–56.

18. Truby kruglye [Circular pipes]. Elektronnyi katalog, prais-list [Electronic catalog]. Available at : www.agrupp.com/pricelist/

19. Sinel'nikov A.S., Orlova A.V. Prochnost' prosechno-rastyazhnogo profilya: ispytaniya i matematicheskoe modelirovanie [Durability of extended profile: testing and mathematical simulation]. Scientific and Technical Journal on Construction and Architecture. 2013. No. 12. Pp. 41–54. (rus)

20. Gordeeva A.O., Vatin N.I. Raschetnaya konechno-elementnaya model' kholodnognutogo perforirovannogo tonkostennogo sterzhnya v programmno-vychislitel'nom komplekse SCAD OFFICE [Estimated finite element model of cold-formed perforated thin-walled bar using SCAD Office software]. Magazine of Civil Engineering. 2011. No. 3. Pp. 36–46. (rus)

21. Vatin N.I., Shatov D.S., Smaznov D.N. Modelirovanie raboty tonkostennoi stal'noi stoiki v SKAD i optimizatsiya rascheta po Evrokodu [SCAD simulation of thin-walled steel beam according to Eurocode]. Proc. Int. Sci. Conf. Peter the Great St.-Petersburg Polytechnic University. 2009. Pp. 212–213. (rus)

22. Tusnin A.R., Tusnina O.A. Vychislitel'naya sistema Stal'kon dlya rascheta i proektirovaniya sterzhnevykh konstruktsii iz tonkostennykh sterzhnei otkrytogo profilya [Computer system Stalcon for calculation and design of beam structures of thin-walled open section]. J. Industrial and Civil Engineering. 2012. No. 8. Pp. 62–64. (rus)

23. Tusnin A.R. Avtomatizatsiya raschetov nesushchei sposobnosti elementov stal'nykh konstruktsii. [Automated calculations of bearing capacity of steel structure elements]. J. Industrial and Civil Engineering. 2010. No. 10. Pp. 22–23. (rus)