Production of full-scale experimental modular specimens of the steel and concrete composite cable space frame

• Autorzy: Gasii G. M.
• Konferencja: II Międzynarodowa Konferencja Naukowo-Techniczna "Problemy Inżynierii Bezpieczeństwa Obiektów Antropogenicznych” (II; 16.11-17.11.2017; Warszawa, Polska)
• Języki publikacji: EN

Abstrakty

EN

The steel and concrete composite cable space frame is a new type of space roof structure that was designed in Poltava National Technical Yuri Kondratyuk University and fully patented. The article presents procedure preparation of prototype of steel and concrete composite cable space frame in full scale. The main focus is on the specifics of the technological operations of preparation and production of steel and concrete elements of the structure. There is technological sequence of operations in the article also. The full-scale experimental structure consists of the space steel and concrete composite modules and flexible modular steel elements, which are combined with each other via single-bolt connections. The space steel and concrete composite module consists of monolithic reinforced concrete slab and a structural lattice that is made from steel tubes. Production of steel parts of structure were carried out at the factory of building structures and concrete performed under conditions close to those of the construction site.

Słowa kluczowe

EN

module; tube; plate; hole; welding; bolt

PL

moduł; rura; płyta; otwór; spawanie; śruba

• Wydawca: Centrum Rzeczoznawstwa Budowlanego Sp. z o.o.
• Czasopismo: Inżynieria Bezpieczeństwa Obiektów Antropogenicznych
• Rocznik: 2017
• Tom: Nr 3-4
• Strony: 13--17
• Opis fizyczny: Bibliogr. 25 poz., rys., tab.

Twórcy

autor

Gasii G. M.

• Ph.D., Associate Professor, Doctoral candidate Poltava National Technical Yuri Kondratyuk University

Bibliografia

• 1. Uy B., Tao Z., Lam D., Han L.H., 2016, Behaviour and Design of Composite Steel and Concrete Building Structures, Boca Raton: CRC Press, 400.
• 2. Knowles P.R., 1973, Composite steel and concrete construction: Monograph, Guildford: University of Surrey, 200.
• 3. Oehlers D.J., Bradford M.A., 2013, Composite Steel and Concrete Structures: Fundamental Behavior, Elsevier, 588.
• 4. Johnson R.P., 2004, Composite Structures of Steel and Concrete: Beams, Slabs, Columns, and Frames for Buildings: Third Edition, Blackwell, 252.
• 5. Storozhenko L.I., Gasii G.M., 2016, Analysis of stressstrain state of the steel-concrete composite ribbed slab as a part of the spatial grid-cable suspended structure. Academic journal. Industrial Machine Building, Civil Engineering, № 2, 81–86.
• 6. Storozhenko L.I., Gasii G.M., 2015, Experimental research of deformability of units of steel and concrete composite grid-cable roof. Construction, materials science, mechanical engineering, №82, 219–225.
• 7. Lam D., 2005, Advances in Composite Construction in the UK. Proceedings of the Second International Symposium on Worldwide Codified Design and Technology in Steel Structures, Hong Kong, 133–144.
• 8. Uy B., 2012, Applications, behaviour and design of composite steel-concrete structures. Advances in Structural Engineering, vol. 15, №9, 1559–1572.
• 9. Gasii G.M., Zabolotskyi O.S., 2016, The effective constructive solutions for the steel and concrete composite space structures. Herald KazGAZA, Almaty: KazGAZA, №3, 94–103.
• 10. Gasii G.M., 2014, Technological and design features of flat-rod elements with usage of composite reinforced concrete. Metallurgical and Mining Industry, №4, 23–25.
• 11. Vayas I., Iliopoulos A., 2013, Design of Steel-Concrete Composite Bridges to Eurocodes, Boca Raton; London; New York: CRC Press, 584.
• 12. Storozhenko L.I., Gasii G.M., 2014, Experimental research of strain-stress state of ferrocement slabs of composite reinforced concrete structure elements. Metallurgical and Mining Industry, №6, 40–42.
• 13. Storozhenko L.I., Gasii G.M., 2016, Velykoprolitni strukturno-vantovi stalezalizobetonni pokryttya dlya budivel’ i sporud aeroportiv. Problemy rozvytku mis’koho seredovyshcha, K.: NAU, №2, 72–79.
• 14. Storozhenko L.I., Gasii G.M., 2015, The new composite designs for mine tunnel support. Scientific Bulletin of National Mining University, №4, 28–34.
• 15. Storozhenko L.I., Gasii G.M, Gapchenko S.A., 2014, The new composite and space grid cable-stayed constructions. Academic journal. Industrial Machine Building, Civil Engineering, Poltava: PoltNTU, №1, 91–96.
• 16. Storozhenko L.I., Gasii G.M, Gapchenko S.A., 2015, The steel and concrete composite cable space frames: Monograph, Poltava: ASMI, 218.
• 17. Storozhenko L.I., Gasii G.M., 2015, Space steel and concrete composite grid-cable roof. Construction, materials science, mechanical engineering, №82, 226–230.
• 18. Gasii G.M., 2016, Designing support node of the steel and concrete composite grid-cable curved slab. Resource economical materials, design, buildings and structures, Rivne: NUVGP, №32, 129–136.
• 19. Storozhenko L.I., Gasii G.M., 2016, The stress-straine state investigation of connection nodes of the steel and concrete composite cable space frames via behavior modeling. Urban and territorial planning, K.: KNUBA, №61, 343–347.
• 20. Gasii G.M., 2016, Analysis of stress-strain state of the trapezoidal steel plate used for joints elements of the bottom chord of the experimental composite steel and concrete grid-cable barrel shell. Collected scientific works of Ukrainian State University of Railway Transport, Kharkov: UkrDUZT, №162, 41–47.
• 21. Gasii G.M., 2016, Napruzheno-deformovanyy stan stalevoyi plastyny pryamokutnoyi formy vuzla z”yednannya stryzhnevykh elementiv strukturnovantovoyi stalezalizobetonnoyi tsylindrychnoyi obolonky. Visnyk ODABA, Odesa: Zovnishreklamservis, №62, 215–219.
• 22. Gasii G.M., 2016, The main points of form finding and designing structure systems from the steel-concrete gridcable composite constructions. Construction, material science, mechanical engineering: scientific works collection, Dnipropetrovsk: SHEE ≪Pridneprovs’ka State Academy of Civil Engineering and Architecture≫, №87, 48–53.
• 23. Storozhenko L.I., Gasii G.M., 2015, Definition of geometrical parameters of steel and concrete composite grid-cable roofs. Resource economical materials, design, buildings and structures, Rivne: NUVGP, №31, 511–516.
• 24. Storozhenko L.I., Gasii G.M., Gapchenko S.A., 2014, Design features and technology of installation of new spatial constructions of composite grid-cable coverings. Eastern-European Journal of Enterprise Technologies, №1, vol. 4, 67–72.
• 25. Storozhenko L.I., Gasii G.M., 2016, The features of structural concept and designing of the full-length experimental module of the composite steel and concrete grid-cable roof. Academic journal. Industrial Machine Building, Civil Engineering. Poltava: PoltNTU, №1, 52–60.

Uwagi

PL

Opracowanie ze środków MNiSW w ramach umowy 812/P-DUN/2016 na działalność upowszechniającą naukę (zadania 2017).