Modeling of the Stress-Strain State of Through-Reinforced Concrete Structures with External Sheeting Reinforcement by the Finite Element Method

[1] Akpoyomare A. I., Okereke M .I., Bingley M. S. Virtual testing of composites: Imposing periodic boundary conditions on general finite element meshes. Composite Structures. № 160, (2017), pp. 983–994. https://doi.org/10.1016/j.compstruct.2016.10.114.

[2] Semko P., Skliarenko S., Semko V. Concrete Filled Tubular Elements Joints Investigation. International Journal of Engineering & Technology. Vol. 7 (3.2), (2018), pp 494‑500. https://doi.org/10.14419/ijet.v7i3.2.14578

[3] Semko O., Dariienko V., Sirobaba V. Deformability of short steel reinforced concrete structures on light concrete. International Journal of Engineering & Technology. Vol. 7 (3.2), (2018), pp. 370–375. https://doi.org/10.14419/ijet.v7i3.2.14555

[4] Storozhenko L.I., Lapenko O.I., Opryshko N.M. «Zihnuti naskrizni konstruktsii z lystovym armuvanniam», Mekhanika i fizyka ruinuvannia budivelnykh materialiv ta konstruktsii., Vyp. 7., Fizyko-mekh. in-t im. H.V.Karpenka, (2007), s. 541 – 545.

[5] Storozhenko L.I., Lapenko O.I., Opryshko N.M. «Stysnuti naskrizni konstruktsii iz strichkovym armuvanniam», Budivelni konstruktsii: Naukovo-tekhnichni problemy suchasnoho zalizobetonu, Vyp.67, NDIBK, (2007), s. 759 – 766.

[6] Storozhenko L.I., Lapenko O.I., Mahas N.M. «Naskrizni stalezalizobetonni konstruktsii iz zovnishnim lystovym armuvanniam dlia odnopoverkhovykh vyrobnychykh budivel», Zb. na-uk. prats «Resursoekonomni materialy, konstruktsii, budivli ta sporudy». – Vyp. 16, ch. 2, NUVHP, (2008), – s. 370 – 375.

[7] Storozhenko L.I., Lapenko O.I., Mahas N.M. «Eksperymentalni doslidzhennia naskriznykh konstruktsii, vyhotovlenykh u neznimnii opalubtsi», Kommunalnoe khoziaistvo horodov, Vyp. 86, Tekhnika, (2009), s.44 – 49.

[8] Mahas N.M., «Naskrizni zalizobetonni konstruktsii z zovnishnim lystovym armuvanniam», Stalezalizobeton. Continuance: zb. nauk. prats. Pid red. Storozhenka L.I., PoltNTU, (2016), s. 245 – 261.

[9] Yermolenko D., Pents V., Golovko G., Murza S. Development of a procedure for the evaluation of the stressed-deformed state of pipe-concrete elements that are stretched off-center. Eastern-European Journal of Enterprise Technologies. Vol. 4/7 (88) 2017, pp. 4 – 9. https://doi.org/10.15587/1729-4061.2017.106844

[10] Piskunov, V. G., Gorik, A. V., & Cherednikov, V. N. (2000). Modeling of transverse shears of piecewise homogeneous composite bars using an iterative process with account of tangential loads 2. resolving equations and results. Mechanics of Composite Materials, 36(6), 445-452. https://doi.org/10.1023/A:1006798314569

[11] Kochkarev, D., Galinska, T., & Tkachuk, O. (2018). Normal sections calculation of bending reinforced concrete and fiber concrete element. International Journal of Engineering and Technology(UAE), 7(3), 176-182. http://dx.doi.org/10.14419/ijet.v7i3.2.14399

[12] Kochkarev, D., & Galinska, T. (2017). Calculation methodology of reinforced concrete elements based on calculated resistance of reinforced concrete. Paper presented at the MATEC Web of Conferences, 116 https://doi.org/10.1051/matecconf/201711602020

[13] Kochkarev, D., Azizov T., & Galinska, T. (2018) Bending deflection reinforced concrete elements determination. Paper presented at the MATEC Web of Conferences, 230 https://doi.org/10.1051/matecconf/201823002012

[14] Leshchenko M. V., Semko V. O. Thermal characteristics of the external walling made of cold-formed steel studs and polystyrene concrete. Magazine of Civil Engineering. № 8, (2015), pp. 44–55. https://doi.org/10.5862/MCE.60.6

[15] Semko O., Yurin O., Avramenko Yu., Skliarenko S. Thermophysical aspects of cold roof spaces. MATEC Web of Conferences. Vol. 116, (2017), р. 02030. https://doi.org/10.1051/matecconf/201711602030