K.A. Amelicheva – Ph.D.(Eng.), Associate Professor,
Kaluga branch of the Bauman MSTU
Е-mail: aka2000@mail.ru
E.V. Vershinin – Ph.D.(Eng.), Head of Department,
Kaluga branch of the Bauman MSTU
Е-mail: yevgeniyv@mail.ru
G.V. Prasitskiy – Assistant,
Kaluga branch of the Bauman MSTU
Е-mail: akatosh74@yandex.ru
V.V. Prasitskiy – Dr.Sc.(Eng.),
Kaluga branch of the Bauman MSTU
Е-mail: sintel40@yandex.ru
The dynamics of given physical properties formation of planar and bulk composite materials has been studied depending on the type and content of the copper component in them. On the example of electrically conductive, emitting and heat- dissipating compositions used as part of electrocontact devices, vacuum and gas-discharge units and semiconductor devices, including the microwave range, required for the assembly of modern technical systems, the main technologies for their production have been analyzed, providing the required operating parameters. These are cold cladding of metals and obtaining multilayer tapes on rolling mills or metal spraying and creating sandwich structures on various substrate materials, mixing initial powders in predetermined proportions, bulk compositions compacting from mixtures on hydraulic presses and their subsequent heat treatment or infiltration in furnaces with a protective atmosphere. Rational ways to modernize the highly sought-after bulk copper-containing compositions and methods for in-creasing their competitiveness have been described.
- Lileev A.S. Fenomenologicheskaya teoriya protsessov peremagnichivaniya postoyannykh magnitov iz splavov. Metallovedenie i termicheskaya obrabotka metallov. – 2016. № 10 (736). S. 4–9. (in Russian)
- Shatalov V.K., Korzhavyi A.P., Lysenko L.V et al. Increasing the strength of titanium alloys using rods process by microarc oxidation. Welding international. 2017. V 31. № 12. P. 964–968.
- Korzhavyi A.P., Maksimov V.V., Fedorov V.O. Poluchenie iskhodnykh materialov dlya elektronnoi komponentnoi bazy radioelektronnogo proizvodstva. Elektromagnitnye volny i elektronnye sistemy. 2016. T. 21. № 1. S. 9-14. (in Russian)
- Fedoseev I.V. Gidrokarbonilnye protsessy v tekhnologii platinovykh metallov. M.: Ruda i Metally. 2011. 128 s. (in Russian)
- Fedoseev I.V., Maksimov V.V. Ispolzovanie gidrokarbonilnogo protsessa v sovremennoi tekhnologii proizvodstva medi. Tsvetnye metally. 2012. № 9. S. 21–24. (in Russian)
- Korzhavyi A.P. Vliyanie ionno-elektronnoi bombardirovki na svoistva kompozitsii metall-dielektrik i razrabotka na ikh osnove dolgovechnykh katodov dlya otpayannykh priborov: Diss. dokt. tekh. nauk. M., 1991. 49 s. [Elektronnyi resurs] URL: https://search.rsl.ru. (in Russian)
- Nikiforov K.G., Korzhavyi A.P., Gorbachev V.V. i dr. Defekty i fizicheskie svoistva mnogokomponentnykh elektronnykh materialov. Pod red. K.G. Nikiforova. Kaluga: Izd-vo KGPU im. K.E. Tsiolkovskogo. 1999. 215 s. (in Russian)
- Gotra Z.Yu. Tekhnologiya mikroelektronnykh ustroistv: spravochnik. M.: Radio i svyaz. 1991. 528 s. (in Russian)
- Gotra Z.Yu., Smerklo L.M., Boiko I.I. i dr. Teploprovodnye podlozhki dlya moshchnykh gibridnykh integralnykh skhem. Zarubezhnaya radioelektronika. 1990. № 12. S. 3–23. (in Russian)
- Ponomarev V.A., Yarantsev N.V. Poroshkovye kompozitsionnye materialy dlya izdelii elektronnoi tekhniki: nauchnoe izdanie. Pod red. A.P. Korzhavogo. M.: Izd-vo MGTU im. N.E. Baumana. 2014. 304 s. (in Russian)
- Iovdalskii V.A., Ganyushkina N.V., Pchelin V.A. i dr. Moshchnaya gibridnaya integralnaya skhema SVCh-diapazona s almaznym teplootvodom. Elektronnaya tekhnika. Ser. SVCh-tekhnika. 2013. № 2 (517) S. 66–74. (in Russian)
- Kataev S.V., Sidorov V.A., Gordeev S.K. Almaz-karbidnyi kompozitsionnyi material «skeleton» dlya teplootvodov. Elektronika. NTB. 2011. № 3. S. 60–64. (in Russian)
- Bolgov I.S., Korzhavyi A.P. Promising directions of development of tape metallic materials for electronics. Journal of Advanced Materials. 1994. V. 1. № 4. P. 350–352.
- Lipnitskii A.G., Nelasov I.V., Klimenko D.N. i dr. Molekulyarno-dinamicheskoe modelirovanie mnogosloinogo kompozita Cu/Nb. Materialovedenie. 2009. № 6. S. 7–10. (in Russian)
- Katalog produktsii AO «Ametist-Stan». Kaluga: Izd-vo AO Ametist-Stan. 2019. 13s. URL: http://www.ametist-stan.ru.
- Korzhavyi A.P., Kapustin V.I., Kuzmin G.V. Metody eksperimentalnoi fiziki v izbrannykh tekhnologiyakh zashchity prirody i cheloveka: monografiya. M.: INFRA-M. 2016. 352 s.
- Korzhavyi A.P. Advanced metallic material for vacuum devices. Journ. of Advanced Materials. 1994. V. 1(1). P. 13–15.
- Korzhavyi A.P., Marin V.P., Reutov A.P. Perspektivnye napravleniya razrabotok materialov dlya vakuumnykh priborov. Naukoemkie tekhnologii. 2001. T. 2. № 4. S. 13–19. (in Russian)
- Korzhavyi A.P., Nikiforov D.K. Emittiruyushchie nanostruktury «metal - oksid metalla»: fizika i primenenie: monografiya. Pod red. A.P. Korzhavogo. M.: Izd-vo MGTU im. N.E. Baumana. 2009. 156 s.
- Bondarenko G.G., Korzhavyi A.P. Influence of surface on the structure and properties of coed cathodes. Russian Physics Journal. 2007. № 50 (2). P. 125–133.
- Chernov N.K. Osnovy tekhnologii poloschatogo plakirovaniya metallov. Kaluga: Izdatelstvo nauchnoi literatury N.F. Bochkarevoi. 2010. 224 s. (in Russian)
- Korzhavyi A.P. Poroshkovaya metallurgiya v materialosberegayushchikh tekhnologiyakh izgotovleniya katodnykh uzlov IET. Elektronnaya promyshlennost. 1986. № 3. S. 48–49. (in Russian)
- Korzhavyi A.P., Redega K.P. Materialy dlya katodov s nizkimi znacheniyami pervogo kriticheskogo potentsiala. Obzory po elektronnoi tekhnike. Ser. Materialy.1987. № 2 (1269). 39s. (in Russian)
- Esaulov M.N. Izmenenie sostava i struktury mnogokomponentnykh metallicheskikh materialov pri bombardirovke ikh poverkhnosti zaryazhennymi vysokoenergeticheskimi chastitsami v elektronnykh priborakh: Avtoref. dic. … kand. tekh. nauk. M., 2005. 16 s. (in Russian)
- Bondarenko G.G., Zhdanov S.M., Korzhavyi A.P., Tikhonov A.N. Povedenie metallicheskikh kompozitsii na osnove medi i alyuminiya v usloviyakh dlitelnoi ionno-elektronnoi bombardirovki. Perspektivnye materialy. 1999. № 3. S. 29–38.
- Li I.P. Magnetrony impulsnogo deistviya – vse delo v katode. Elektronika. NTB. 2012. № 5. S. 84–87. (in Russian)
- Aristarkhova A.A., Volkov S.S., Korzhavyi A.P. i dr. Izmenenie vtorichno-emissionnykh svoistv i sostava kompozitsionnykh plenochnykh emitterov Cu/MgO na Cu v protsesse aktivirovaniya. Elektronnaya tekhnika. Ser. Materialy. 1987 № 4 (225). S. 19–21. (in Russian)
- Korzhavyi A.P. Kompozitsionnye emittiruyushchie materialy. Obzory po elektronnoi tekhniki. Ser. Materialy. 1988. № 5 (1368). 65s. (in Russian)
- Semenova V.B., Korzhavyi A.P. Metody razrabotki i konstruktivnye osobennosti elektrodnykh sistem sovremennykh gazovykh lazerov. Lazernaya tekhnika i optoelektronika. 1982. № 3 S. 71. (in Russian)
- Shatalov V.K., Korzhavyi A.P. Mikrodugovoe oksidirovanie v tekhnike sozdaniya emitiruyushchikh nanostruktur lazernykh gazorazryadnykh datchikov. Elektromagnitnye volny i elektronnye sistemy. 2016. T. 21. № 1. S. 78–84. (in Russian)
- Gnesin G.G., Levchenko G.V., Luban R.B. Novye elektrodnye materialy dlya gazorazryadnykh kamer tekhnologicheskikh lazerov. Elektronnaya promyshlennost. 1989. № 2. S. 35. (in Russian)
- Kachalin N.I., Belov V.Yu., Tikhii G.A. i dr. Psevdosplav Cu-W v kachestve dugogasitelnykh kontaktov dlya sovremennykh elegazovykh vyklyuchatelei. Zagotovitelnye proizvodstva v mashinostroenii. 2007. № 1. S. 35–43. (in Russian)
- Korzhavyi A.P., Marin V.P., Yarantsev N.V. Perspektivnye lentochnye metallicheskie materialy dlya elektronnoi tekhniki. Naukoemkie tekhnologii. 2001. T. 2. № 4. S. 50–56. (in Russian)
- Bondar D. Moshchnye SVCh-tranzistory i korpusa dlya rossiiskogo i zarubezhnogo rynka. Elektronnye komponenty. 2013. № 1. S. 23. (in Russian)
- Patent RF № 2628233. Sposob izgotovleniya izdelii iz psevdosplavov molibden-med. A.P. Korzhavyi, G.V. Prasitskii. Opubl. 15.08.2017. Byul. № 23. (in Russian)
- Patent RF № 2607478. Sposob izgotovleniya izdelii iz psevdosplavov volfram-med. A.P. Korzhavyi, G.V. Prasitskii. Opubl. 10.01.2017. Byul. № 1. (in Russian)
- Bodrova L.V., Goida E.Yu., Pastukhov E.A., Chentsov V.P. Optimizatsiya sposobov zhidkofaznogo polucheniya kompozitsionnykh splavov Cu-W. Perspektivnye materialy. 2017. № 7. S. 54–61. (in Russian)
- Tikhii G.A. Struktura, svoistva i tekhnologii polucheniya tugoplavkikh psevdosplavov W-Ni-Fe i Mo-Cu pri ispolzovanii mikhanoaktivirovannoi poroshkovoi shikhty: Avtoref. dic. … kand. tekh. nauk. Samara. 2001. 20s. (in Russian)
- Korzhavyi A.P., Inyukhin M.V. Primenenie psevdosplavov sostava volfram-med dlya otvoda tepla v korpusakh silovykh poluprovodnikovykh priborov. Elektromagnitnye volny i elektronnye sistemy. 2016. T. 21. № 8. S. 10–15. (in Russian)
- Rajkumar K. Aravindan S. Microwave sintering of copper-graphite composites. Journal of Materials Processing Technology. 2009. V. 209. № 15. P. 5601–5605.
- Ponradzh°Vidzhai N., Azhaguradzhan A., Vettivel S.K. i dr. Modelirovanie i optimizatsiya vliyaniya parametrov spekaniya na tverdost kompozitnykh listov med/grafen po metodike poverkhnosti otklika. Metallovedenie i termicheskaya obrabotka metallov. 2018. № 9 (759). S. 57–61. (in Russian)
- Rylkov E.N., Isupov F.Yu., Naumov A.A. i dr. Mikrostruktura i mekhanicheskie svoistva raznorodnykh soedinenii Al-Cu poluchennykh svarkoi treniem s peremeshivaniem. Metallovedenie i termicheskaya obrabotka metallov. 2018. № 11 (761). S. 48–53. (in Russian)
- Patent RF № 2175804. Gazovyi lazer na tleyushchem razryade. G.M. Kalistratova, V.N. Kazakov, A.P. Korzhavyi i dr. Opubl. 18.05.2000. Byul. № 5. (in Russian)
- Marin V.P., Vlasko A.V., Pchelintseva N.I. i dr. Novye tekhnologii polucheniya kompozitsionnykh materialov, obespechivayushchikh povyshennyi resurs. Naukoemkie tekhnologii. 2008. T. 9., № 10. S. 4–9.
- Isaev S.I., Kozhinov I.V., Kofanov V.I. i dr. Teoriya teploprovodnosti /pod red. A.I. Leonteva. M.: Izd-vo MGTU im. N.E. Baumana. 2018. 462s. (in Russian)
- Marin V.P., Fedorov V.K., Lutsenko A.V. Osnovy teorii nanotekhnologii. M.: Izd-vo «MATI RGTU im. K.E. Tsiolkovskogo». 2013. 128s. (in Russian)