Basic approaches and requirements for the design of tribological polymer composite materials with high-modulus fillers

Authors

  • V.V. Aulin Central Ukrainian National Technical University
  • A.V. Hrinkiv Central Ukrainian National Technical University
  • V.V. Smal Central Ukrainian National Technical University
  • S.V. Lysenko Central Ukrainian National Technical University
  • M.V. Pashynskyi Central Ukrainian National Technical University
  • S.E. Katerynych Central Ukrainian National Technical University
  • O.M. Livitskyi Central Ukrainian National Technical University

DOI:

https://doi.org/10.31891/2079-1372-2021-102-4-51-60

Keywords:

polymer composite material, high-modulus filler, tribotechnical system, system-oriented approach, synergetic concept

Abstract

Based on a combination of a system-oriented approach and a synergetic concept, the requirements for the design of tribological polymer composite materials with high-modulus fillers are formed. These materials are considered as an open dynamic system that evolves during operation. The principles of the synergetic concept for tribotechnical systems taking into account the theory of evolution and self-organization to ensure its self-governing and self-supporting development are considered. It is revealed that in the process of interaction of elements of the tribosystem the cooperation of local areas of their materials is formed with the emergence of a critical number of such areas and the creation of an information field about their functioning. The direction of self-organization of processes and states of parts materials in the tribotechnical system and expediency of using the conclusions of the synergetic concept in the construction of polymer composite materials, as well as their nonequilibrium are shown. The issues of creation of tribophysical bases of wear resistance of tribotechnical systems with conjugations of the details made or strengthened by polymeric composite materials are considered. Polymer composite materials are considered as a set of interacting ensembles of local areas, the principle of maximum wear resistance (reliability) is used. Tribological principles and requirements to creation and substantiation of expediency and efficiency of use of high-modulus fillers in polymers are formulated

References

1. Aleksandrov E.E., Kravets I.A., Lyisikov E.P. i dr. (2006) Povyishenie resursa tehnicheskih sistem putyom ispolzovaniya elektricheskih i magnitnyih poley: monografiya. [H.: NTU "HPI"]. – 544 s.
2. Devoyko O.G., Kardapolova M.A. (2003) Sozdanie kompozitsionnyih pokryitiy na osnove smesey s ispolzovaniem lazernogo nagreva [Sb.nauch.rabot PGTU. – Novopolotsk]. – S.141-144.
3 Beloysov V.Ya. (1984) Dolgovechnost detaley mashin s kompozitsionnyimi materialami [Lviv: Vyshcha shkola]. – 180 s.
4. Malikov I.I., Ivanov V.D., Kotyagov L.F. i dr. (1985) Vliyanie kompozitsionnyih pokryitiy na kachestvo prirabotki i iznosostoykost truschihsya sopryazheniy avtotraktornyih dvigateley [Trenie i iznos, 1985. – T. VI, № 1]. – S. 125-132.
5. Vanin G.A. (1985) Mikromehanika kompozitsionnyih materialov: monografiya [K.: Nauk. dumka]. – 304s.
6. Bondarenko V.P. (1987) Tribotehnicheskie kompozityi s vyisokomodulnyimi napolnitelyami [K.: Nauk. dumka]. – 232 s.
7. Borodin I.N. (1982) Uprochnenie detaley kompozitsionnyimi pokryitiyami [M.: Mashinostroenie]. – 141 s.
8. Savuliak V.I. (2004) Naukovi zasady formuvannia na splavakh zaliza kompozytsiinykh metalokarbidnykh shariv zi stabilnymy strukturamy ta pidvyshchenymy trybotekhnichnymy kharakterystykamy [avtoref. dys... d-ra tekhn. nauk: 05.02.01]. – 39 s.
9. Aulin V.V. Trybofizychni osnovy pidvyshchennia znosostiikosti detalei ta robochykh orhaniv silskohospodarskoi tekhniky [avtoref. dys. ... d-ra tekhn. nauk : 05.02.04]. – 36 s.
10. Fedorchenko I.M. (1980) Kompozitsionnyie spechennyie antifriktsionnyie materialyi [K.: Naukova dumka]. – 404 s.
11. Suh N.P. (1978) The delamination theory of wear [Wear, Vol.1]. – P1-162.
12. Suh N.P. (1975) The delamination theory of wear [Massachusetts Institute of Technology]. – 158p.
13. Suh N.P. (1973) The delamination theory of wear [Wear, Vol.25 - №1973]. – P 11-124.
14. Ashby M.F., Jones D.R.H. (1996) Engineering Materials [Oxford: Butterworth-Heinemann]. – 322p.
15. Kanovich M.Z., Trofimov N.N. (2003) Soprotivlenie kompozitsionnyih materialov: monografiya [M.: Mir]. – 504 s.
16. Kompozitsionnyie materialyi. Spravochnik (1985) / Pod red. D.M. Karpinosa [K.: Naukova dumka]. – 592 s.
17. Sorokov S. (2003) Klasternyi pidkhid do rozrakhunku fizychnykh kharakterystyk kompozytnykh materialiv [Lviv: In-t fizyky kondens. system NANU]. – 23 s.
18. Gerland Dzh. (1976) Razrushenie kompozitov s dispersnyimi chastitsami v metallicheskoy matritse. Kompozitsionnyie materialyi [M.:Mir] S.105-130.
19. Ivanochkin P.G. (2009) Kontaktnyie zadachi dlya uzlov treniya s dvuhsloynyimi kompozitsiyami tribotehnicheskogo naznacheniya [avtoref. diss. na soisk. uch. stepeni d-ra tehn. nauk.: spets.01.02.04, 05.02.04]. – 38s.
20. Pribyitkov G.A. (2002) Mezhfaznyiy massoperenos na granitse metallov i tugoplavkih soedineniy s metallicheskimi rasplavami i ego rol v formirovanii strukturyi kompozitsionnyih materialov i pokryitiy [avtoref. diss. na soiskanie uchenoy stepeni d-ra. tehn. nauk: spets. 05.16.01]. – 40 s.
21. Sokolovskaya E.M., Guzey L.S. (1978) Fizikohimiya kompozitsionnyih materialov [M.: Mosk. un-ta] – 256 s.
22. Adirovich E., Blohkhinzev D. (1943) On the Forces of Dry Friction. [J.Phys. USSR. - 1943, V 7, №1] – P.29-36.
23. Kryisov S.V. (1992) Volnovyie protsessyi pri kontaktnyih vzaimodeystviyah podvizhnyih sopryazheniy v uprugih elementah mashin i konstruktsiy [avtoref. dis. nauk. stepeni kand. fiz.-mat. nauk: spets. 01.02.06]. – 23s.
24. Boroday A.V. (2007) O protsessah samoinduktsii v tribosistemah [Trenie i smazka v mashinah i mehanizmah. – M.: Mashinostroenie. – № 2]. – S. 3-10.
25. Boroday A.V., Klimenko A.V., Ponomarev V.I. (2005) O friktsionnom vzaimodeystvii tel kak induktsionnom i tunnelnom protsesse [Izv. vuzov. Sev. – Kavk. region. Tehn. nauki. Spetsvyip. Problemyi triboelektrohimii]. – S. 36-42.
26. Bershadskiy L.I. (1981) Samoorganizatsiya i nadezhnost tribosistem [Kiev]. – 35 s.
27. Bershadskiy L.I. (1982) Osnovyi teorii strukturnoy prisposablivaemosti i perehodnyih sostoyaniy tribosistem i ee prilozhenie k zadacham povyisheniya nadezhnosti zubchatyih i chervyachnyih peredach [Dis. ... d-ra tehn. nauk]. – K. – 328 s.
28. Bershadskiy L.I. (1990) Strukturnaya termodinamika tribosistem [K.: Znanie]. – 30 s.
29. Klementev N.M. (1971) Termodinamika treniya [Voronezh: Voronezhsk. politehi, in-t]. – 305s.
30. Praca naukowo_badawcza. Laboratoryjne i eksploatacyjne badania teflonowego SLIDER 2000. WSI w Radomiu. Radom. 1993. – 36р.
31. Andrianov I.V., Barantsev R.G., Manevich L.I. (2004) Asimptoticheskaya matematika i sinergetika: put k tselostnoy prostote [M.: Editorial URSS] – 304 s.
32. Gershman I.S. (2009) Sinergetika protsessov treniya [Trenie, iznos, smazka. T.12, №40]. – S.1-8.
33. Ershov S.V. (1993) Sinergetika. Novyie napravleniya. Nelineynyie volnyi [Fizika i astrofizika. – M.: Nauka]. – S. 306–319.
34. Knyazeva E.N., Kurdyumov S.P. (2002) Osnovaniya sinergetiki. Sinergeticheskoe mirovidenie [SPb.: "Aleteyya"]. – 414 s.
35. Kostetskiy B.I. (1976) Poverhnostnaya prochnost materialov pri trenii [Kiev: Tehnika] – 296 s.
36. Kostetskiy B.I. (1981) Fundamentalnyie zakonomernosti treniya i iznosa [Kiev: Znanie] – 31 s.
37. Kragelskiy I.V. (1968) Trenie i iznos [M.:Mashinostroenie]. – 480 s.
38. Lyubarskiy I.M., Palatnik L.S. (1976) Metallofizika treniya [M.: Metallurgiya]. – 176 s.
39. Naydyish V.M. (2004) Kontseptsii sovremennogo estestvoznaniya [M.: Alfa – M; INFRA-M]. – 622s.
40. Aulin V.V. (2014) Fizychni osnovy protsesiv i staniv samoorhanizatsii v trybotekhnichnykh systemakh: monohrafiia [Kirovohrad: Vyd. Lysenko V.F.]. – 370 s.
41. Butkovskiy O.Ya. (1996) Narushenie simmetrii pri byistryih bifurkatsionnyih perehodah [zhurn. eksperim. i teoret. fiziki. T.109, Vyip. 6]. – S. 2201–2207.
42. Dorodnitsyin V.A., Elenin G.G. (1988) Simmetriya nelineynyih yavleniy. Kompyuteryi i nelineynyie yavleniya. Informatika i sovremennoe estestvoznanie. [M.: Nauka]. – S. 123–191.
43. Uhtomskiy D.A. (2002) Dominanta. Stati raznyih let [SPb.: Piter]. – 448 s.
44. Printsipyi samoorganizatsii. Per. s angl. A.Ya. Lernera (1966) [M.:Mir]. – 621 s.
45. Katok A.B., Hasselblat B. (2005) Vvedenie v sovremennuyu teoriyu dinamicheskih sistem [M.: Faktorial]. – 767 s.
46. Koronovskiy A.A., Trubetskov D.I. (2002) Nelineynaya dinamika v deystvii [Saratov: Gos. UNTs "Kolledzh"]. – 324 s.
47. Preobrazhenskiy N.G. (1993) Dinamika razvitiya fiziki neravnovesnyih sistem [Edinstvo fiziki. – Novosibirsk: Nauka]. – S. 158–174.
48. Budanov V.G. (2006) O metodologii sinergetiki [Voprosyi filosofii. – № 5]. – S. 79-94.
49. Soroko E.M. (2006) Zolotyie secheniya, protsessyi samoorganizatsii i evolyutsii sistem: Vvedenie v obschuyu teoriyu garmonii sistem [M.: KomKniga]. – 264 s.
50. Glensdorf P., Prigozhin I. (2003) Termodinamicheskaya teoriya strukturyi, ustoychivosti i fluktuatsiy [M.: URSS]. – 280 s.
51. Nikolis G., Prigozhin I. (1979) Samoorganizatsiya v neravnovesnyih sistemah. Ot dissipativnyih struktur k uporyadochennosti cherez fluktuatsii: monografiya [M.: Mir]. – 512 s.
52. Эбелинг В., Энгель А., Файстель Р. Физика процессов эволюции. Синергетический подход [М.: Эдиториал УРСС]. – 328 с.
53. Aulin V.V. (2010) Zahalni zakonomirnosti evoliutsii ta samoorhanizatsii v trybosystemakh [Suchasni problemy trybolohii: Tezy dopovidei Mizhnar. nauk.-tekhn. konf. – K.:IVTs ALKON NAN Ukrainy]. – S.94.
54. Aulin V.V. (2011) Fizychni osnovy evoliutsii staniv trybosystem ta protsesiv samoorhanizatsii yikh elementiv [Zb. m-liv mizhnar. nauk.-prakt. konf. "Olviiskyi forum - 2011", 8-12 chervnia 2011 – Yalta]. – S.14-15.
55. Aulin V.V. (2012) Osnovni synerhetychni komponenty proiavu riznykh form samoorhanizatsii v trybotekhnichnykh systemakh [Zb. m-liv mizhnar. nauk.-prakt. konf. "Olviiskyi forum-2012", 6-10 chervnia 2012, – Yalta., t. 12]. – S.60-62.
56. Aulin V.V. (2014) Systemno-spriamovanyi pidkhid ta synerhetychna kontseptsiia realizatsii protsesiv i staniv samoorhanizatsii materialiv elementiv, robochykh ta tekhnolohichnykh seredovyshch trybotekhnichnykh system [Zb. nauk. prats KNTU/ Tekhnika v s/h vyrobnytstvi, haluzeve mashynobud., avtomatyzatsiia, vyp. 27. – Kirovohrad]. – S.78-87.
57. Nikolis G., Prigozhin I. (1979) Samoorganizatsiya neravnovesnyih sistem: monografiya [M.: Mir]. – 635 s.
58. Pelyuhova E.B., Fradkin E.E. (1997) Samoorganizatsiya fizicheskih sistem [SPb.: SPbGU]. – 324 s.
59. Polak L.S., Mihaylov A.S. (1983) Samoorganizatsiya v neravnovesnyih fiziko-himicheskih sistemah [M.: Nauka]. – 285 s.
60. Prigozhin I.R., Konderudi D. (2002) Sovremennaya termodinamika. Ot teplovyih dvigateley do dissipativnyih struktur [M.: Mir] – 319 s.
61. Stratonovich R.L. (1985) Nelineynaya neravnovesnaya termodinamika [M.: Nauka]. – 480 s.
62. Skott E. (2007) Nelineynaya nauka: rozhdenie i razvitie kogerentnyih struktur [M.: Fizmatlit]. – 560s.
63. Emelyanov S.V., Korovin S.K. (1997) Novyie tipyi obratnoy svyazi: upravlenie pri neopredelennosti [M.: Nauka]. – 352 s.
64. Tverdohlebov V.A. (2009) Nelineynost kak dominanta Prirodyi [Rossiyskiy himicheskiy zhurnal. – T.LIII, № 6] – S.3-6.
65. Dulesov A.S., Semenova M.Yu., Hrustalev V.I. (2011) Svoystva entropii tehnicheskoy sistemyi [Fundamentalnyie issledovaniya. – №8]. – S. 631-636.
66. Prangishvili I.V. (2003) Entropiynyie i drugie sistemnyie zakonomernosti. Voprosyi upravleniya slozhnyimi sistemami [M.: Nauka]. – 428 s.
67. Korolkov B.P. (2011) Termodinamicheskie osnovyi samoorganizatsii: monografiya [Irkutsk: IrGUPS]. – 120 s.
68. Aulin V.V. (2009) Pidvyshchennia nadiinosti trybosystem realizatsiieiu protsesiv samoorhanizatsii [M-ly III mizhnar. nauk.-tekhn. konf.: "Suchasni problemy trybotekhniky", 7-9 zhovtnia 2009r. – Mykolaiv: NUK].-S 15-17.
69. Kuzmenko A.G. (2011) Nadezhnost uzlov treniya po prochnosti i iznosu [Hmelnitskiy:HNU].–391s.
70. Bushe N.A. (2003) Rol neobratimyih protsessov v sovmestimosti tribosistem [Zheleznyie dorogi mira. – №2]. – S.38-41.
71. Kanarchuk V.E. (1986) Adaptatsiya materialov k dinamicheskim vozdeystviyam [Kiev: Naukova dumka]. – 264 s.
72. Костецкий Б.И., Зазимко О.В., Зелинский А.М. (1986) Расчет интенсивности изнашивания при нормальном трении [В кн.: Применение новых материалов, заменителей и систем смазки в узлах трения машин и оборудования – Воронеж, 1986. – С.35-38.

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2021-12-23

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Aulin, V., Hrinkiv, A., Smal, V., Lysenko, S., Pashynskyi, M., Katerynych, S., & Livitskyi, O. (2021). Basic approaches and requirements for the design of tribological polymer composite materials with high-modulus fillers. Problems of Tribology, 26(4/102), 51–60. https://doi.org/10.31891/2079-1372-2021-102-4-51-60

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