Development of Multifunctional Composites Based on Ultrahigh Molecular Weight Polyethylene

[1] V.S. Cherednichenko, Materials Science. Technology of construction materials (Moscow: Electrical Engineering, Electrical Engineering and Electrical Technology), (2006).

Google Scholar

[2] A.E. Raskutin, Strategija razvitija polimernyh kompozicionnyh materialov Aviacionnye materialy i tehnologii. (2017) 344-348.

Google Scholar

[3] E.G. Seljutin, Ju.Ju. Gavrilov, E.N. Voskresenskaja, V.A. Zakharov, V.E. Nikitin, V.A. Polubojarov, Kompozicionnye materialy na osnove sverhvysokomolekuljarnogo polijetilena: svojstva, perspektivy ispol'zovanija Himija v interesah ustojchivogo razvitija. 18 (2010) 375-388.

Google Scholar

[4] S.N. Danilova, A.A. Okhlopkova, A.A. Gavril'yeva, T.A. Okhlopkova, R.V. Borisova, A.A. D'yakonov, Iznosostoykiye polimernyye kompozitsionnyye materialy s uluchshennym mezhfazovym vzaimodeystviyem v sisteme «polimer – volokno» Vestnik Severo-Vostochnogo federal'nogo universiteta im. M.K. Ammosova. 5 (2016) 80-92.

Google Scholar

[5] I.A. Barvinskiy, I.E. Barvinskaya, Spravochnik po lit'yevym termoplastichnym materialam, Svoystva, primery primeneniya, pererabotka, torgovyye marki, izgotoviteli. Spravochnik na CD. Versiya 1.3. Inzhenernaya firma «AB Universal», (2004).

Google Scholar

[6] O.A. Ammosova, A.G. Argunova, G.V. Botvin, O.N. Burenina, S.V. Vasil'yev, M.A. Vasil'yeva, O.V. Gogoleva, M.L. Davydova, E.V. Danzanova, V.E. Kopylov, P.N. Petrova, E.S. Petukhova, M.E. Savvinova, M.D. Sokolova, A.L. Fedorov, A.R. Khaldeyeva, A.A. Khristoforova, N.V. Shadrinov, Modifitsirovannyye polimernyye i kompozitsionnyye materialy dlya severnykh usloviy (Novosibirsk: Izd-vo SO RAN), (2017).

Google Scholar

[7] E.S. Petukhova, Polietilenovyye kompozity s poverkhnostno-obrabotannymi bazal'tovymi i uglerodnymi voloknami Voprosy materialovedeniya. 3 (2017) 148-156.

Google Scholar

[8] V.M. Buznik, E.N. Kablov, Sostojanie i perspektivy arkticheskogo materialovedenija Vestnik Rossijskoj akademii nauk. 87 (2017) 827-839.

Google Scholar

[9] E.N. Kablov, Tendentsii i oriyentiry innovatsionnogo razvitiya Rossii, M.: Izd-vo VIAM, (2015).

Google Scholar

[10] S.V. Panin, V.E. Panin, L.A. Korniyenko, T. Puvadin and others, Modifitsirovaniye sverkhvysokomolekulyarnogo polietilena (SVMPE) nanonapolnitelyami dlya polucheniya antifriktsionnykh kompozitov, Izvestiya VUZov. Khimiya i khimicheskaya tekhnologiya. 54 (2011) 102-106.

Google Scholar

[11] A.A. Okhlopkova, P.N. Petrova, O.V. Gogoleva, Iznosostoykiye kompozitsionnyye materialy na osnove sverkhvysokomolekulyarnogo polietilena dlya ekspluatatsii v ekstremal'nykh usloviyakh, Materialovedeniye. 9 (2011) 10-13.

Google Scholar

[12] O.V. Gogoleva, P.N. Petrova, E.S. Kolesova, Development of Polymer Composite Materials Based on Ultrahigh-Molecular Weight Polyethylene and Carbon Fillers Materials Science Forum. 945 (2019) 362-368.

DOI: 10.4028/www.scientific.net/msf.945.362

Google Scholar

[13] O.V. Gogoleva, P.N. Petrova and E.S. Kolesova, Issledovaniye vliyaniya uglerodnykh volokon na svoystva i strukturu kompozitov na osnove sverkhvysokomolekulyarnogo polietilena Trudy VIII Yevraziyskogo simpoziuma po problemam prochnosti materialov i mashin dlya regionov kholodnogo klimata, EURASTRENCOLD II. (2018) 101-108.

DOI: 10.17223/9785946217408/270

Google Scholar

[14] S.V. Panin, L.A. Korniyenko, S. Vannasri, S. Piriyaon, T. Puvadin and others, Vliyaniye mekhanicheskoy aktivatsii, ionnoy implantatsii i tipa napolniteley na formirovaniye plenki perenosa pri tribosopryazhenii kompozitov na osnove SVMPE, Mekhanika kompozitnykh materialov. 47 (2011) 727-738.

Google Scholar

[15] D.I. Chukov, Formirovaniye struktury i svoystv kompozitsionnykh materialov na osnove sverkhvysokomolekulyarnogo polietilena, armirovannykh uglerodnymi voloknami: avtoreferat dis. kandidata tekhnicheskikh nauk: 05.16, Moskva, (2013).

Google Scholar

[16] K.A. Abdulkhakov, V.M. Kotlyar, K voprosu o polzuchesti polimernykh i kompozitnykh materialov, Vestnik Kazanskogo tekhnologicheskogo universiteta. 8 (2011) 102-107.

Google Scholar

[17] I.P. Nikolayeva, L.I. Ogorodov, S.V. Krasikov, Polzuchest' polietilena vysokoy prochnosti pri razlichnykh rezhimakh nagruzheniya, Stroitel'stvo unikal'nykh zdaniy i sooruzheniy. 12 (2014) 49-63.

Google Scholar

[18] S.A. Khatipov, N.A. Artamonov, Sozdaniye novogo antifriktsionnogo i uplotnitel'nogo materiala na osnove radiatsionno-modifitsirovannogo politetraftoretilena, Rossiy-skiy khimicheskiy zhurnal. 52 (2008) 89–97.

Google Scholar

[19] X.B. Shi, C.L. Wu, M.Z. Rong, T. Czigany, W.H. Ruan, M.Q. Zhang, Improvement of creep resistance of polytetra-fluoroethylene films by nano-inclusions, Chinese Journal of Polymer Science. 31 (2013) 377−387.

DOI: 10.1007/s10118-013-1225-8

Google Scholar

[20] V.P. Radchenko, M.N. Saushkin, Polzuchest' i relaksatsiya ostatochnykh napryazheniy v uprochnonnykh konstruktsiyakh (Moscow: Mashinostroyeniye), (2005).

Google Scholar

[21] T. J. B. Taweel, E. Sokolova, V. Sergeev, D. B. Solovev, Energy and Exergy Analysis of Clinker Cooler in the Cement Industry. IOP Conference Series: Materials Science and Engineering. 463 (2018) paper № 032101. [Online]. Available: https://doi.org/10.1088/1757-899X/463/3/032101.

DOI: 10.1088/1757-899x/463/3/032101

Google Scholar