[1]
V.I. Golovanov, E.V. Kuznecova, Jeffektivnye sredstva ognezashhity dlja stal'nyh i zhelezobetonnyh konstrukcij, Promyshlennoe i grazhdanskoe stroitel'stvo. 9 (2015) 82-90.
Google Scholar
[2]
V. I. Golovanov, V. V. Pavlov, A. V. Pehotikov, Jeksperimental'nye i analiticheskie issledovanija ognestojkosti sploshnoj betonnoj plity so stal'noj i kompozitnoj armaturoj, Pozharnaja bezopasnost'. 2 (2013) 44-51.
Google Scholar
[3]
A. Kovalov, Y. Otrosh, S. Vedula, О. Danilin, Т. Kovalevska, Parameters of fire-retardant coatings of steel constructions under the influence of climatic factors, Naukovyi Visnyk Natsionalnoho Hirnychoho Universytetu. 3 (2019) 46-53.
DOI: 10.29202/nvngu/2019-3/9
Google Scholar
[4]
N.S. Novikov, Ognestojkost' i prochnost' konstrukcij iz fibrobetona, Internet-zhurnal Tehnologii tehnosfernoj bezopasnosti,. 3 (67) (2016) 122-127.
Google Scholar
[5]
A. Vasilchenko, E. Doronin, O. Chernenko, I. Ponomarenko, Estimation of fire resistance of bending reinforced concrete elements based on concrete with disperse fibers, In IOP Conference Series: Materials Science and Engineering. 708 (1) (2019) p.012075.
DOI: 10.1088/1757-899x/708/1/012075
Google Scholar
[6]
Young-Sun Heo, Jay G. Sanjayan, Cheon-Goo Han, Min-Cheol Han, Synergistic effect of combined fibers for spalling protection of concrete in fire, Cement and Concrete Research. 40 (2010) 1547-1554.
DOI: 10.1016/j.cemconres.2010.06.011
Google Scholar
[7]
João Paulo C. Rodrigues, Luys Laím, António Moura Correia, Behaviour of fiber reinforced concrete columns in fire, Composite Structures. 92 (2010) 1263-1268.
DOI: 10.1016/j.compstruct.2009.10.029
Google Scholar
[8]
V. P. Ol'shanskij, Nestacionarnye kolebanija oscilljatora peremennoj massy s uchetom vjazkogo trenija, Vibracii v tehnike ta tehnologijah. 3 (75) (2014) 18–27.
Google Scholar
[9]
V. P. Ol'shanskij, Nestacionarnye kolebanija mehanicheskoj sistemy linejno-peremennoj massy s kombinirovannym treniem, Visnyk Natsionalnoho tekhnichnoho universytetu «Kharkivskyi politekhnichnyi instytut». 4 (1041) (2013) 324-333.
Google Scholar
[10]
N. A. Taranuha, Issledovanie kolebanij sudovyh sterzhnevyh konstrukcij s uchetom soprotivlenija vneshnej sredy razlichnoj plotnosti, Uchenye zapiski KnAGTU. 3 (2015) 82-94.
Google Scholar
[11]
Ju. S. Krutij, Rol' metoda prjamogo integrirovanija v sovremennoj mehanike, Suchasni problemy mekhaniky ta matematyky, Instytut prykladnykh problem mekhaniky i matematyky im. Ya.S. Pidstryhacha NAN Ukrainy. T.1 (2013) 146-148.
DOI: 10.15407/apmm
Google Scholar
[12]
D.V. Lazarieva, M.M. Soroka, O.S. Shyliaiev, Pryiomy roboty z PK ANSYS pry rozviazanni zadach mekhaniky, Odesa, 2020, 432 s.
Google Scholar
[13]
Ju.S. Krutij, Prodol'nye kolebanija neodnorodnogo prjamogo sterzhnja peremennogo sechenija s nepreryvno raspredelennoj massoj, Stroitel'naja mehanika i raschet sooruzhenij. 1 (2011) 25- 33.
Google Scholar
[14]
Yu. S. Krutii, Tochnyi rozviazok dyferentsialnoho rivniannia vymushenykh pozdovzhnikh kolyvan sterzhnia z dovilnymy neperervnymy parametramy, Visnyk Khmelnytskoho natsionalnoho universytetu. 6 (2015) 23-29.
Google Scholar
[15]
M. V. Vasylenko Teoriia kolyvan i stiikosti rukhu, 2004, 525 s.
Google Scholar
[16]
Y. S. Krutii, Rozrobka metodu rozv'yazannya zadach stiykosti i kolyvanʹ deformivnykh system zi zminnymy neperervnymy parametramy, Sc.D. diss., Lutsk National Technical University, (2016).
Google Scholar