Оптимізація процесу керування тліючим розрядом як джерела нагріву при дифузійному зварюванні
DOI:
https://doi.org/10.25140/2411-5363-2023-2(32)-16-25Ключові слова:
дифузійне зварювання; тліючий розряд; керування нагрівом; газорозрядна плазмаАнотація
На основі методів математичного планування експерименту визначено основні керуючі впливи, що характеризують зварювальний нагрів у тліючому розряді, серед яких є розрядний струм (Iр), який визначає загальну потужність, що виділяється в розрядному проміжку, та тиск газу (P), який змінює питомі енергетичні характеристики розряду.
Посилання
Mazanko, V. F., Falchenko, Iu.V., Novomlynets, O.O., Nahorna, I.V., & Yushchenko, S.M. (2021). Investigation of Mass-Transfer Features with Usage of Ion-Modified Blocking Layer in Commuting Plate of Thermoelements. Metallofiz. Noveishie Tekhnol., 43(2), 209-217.
Petrushynets L.V., Falchenko I.V., Ustinov A.I., Novomlynets, O.O., & Yushchenko, S.M. (2019). Vacuum Diffusion Welding of Intermetallic Alloy ɣ-TiAl with High-Temperature Alloy EI437B Through Nanolayered Interlayers. 2019 IEEE 2nd Ukraine Conference on Electrical and Computer Engineering
(UKRCON) (pp. 542-546).
Kotelnikov, D.I. (1976). Tehnologicheskie osobennosti primeneniya tleyushego razryada pri svarke [Technological features of glow discharge application while welding]. Tehnologiya i organizaciya proizvodstva – Technology and organization of production, (7), 57-59.
Kotelnikov, D.I. (1968). Nagrev tleyushim razryadom pri diffuzionnoj svarke [Heating by glow discharge while diffusion welding]. Vestnik Kiev. politehn. In-ta. Ser. «Mashinostroenie» – Bulletin of the Kyiv Polytechnic Institute. Series “Engineering”, (5), 56-60.
Kotelnikov, D.I., & Krisanov, Yu.N. (1979). Raspredelenie plotnosti toka v katodnom pyatne tleyushego razryada [Destrebution of current density in a cathode spot of a glow discharge] Avtomaticheskaya svarka – Automatic conflict, (11), 27-29.
Lima, R.S., & Marpel, B.R. (2007). Thermal Spray Coatings Engineered from Nanostructured Ceramic Aglomerated Powder for Structural, Thermal Barier and biomedical Applications: A Review. Journal of Thermal Spray Technology, 16(1), 40-63.
Smirnov, I.V., Chorniі, A.V., Kalashnikova, I.A., & Seliverstov, I.A. (2009). Zastosuvannya kompozicijnih poroshkiv sistemi Al2O3-Ti-Cu dlia pidvishennia koroziinoi stiikosti plazmovykh pokrittiv [The use of composite powders of the Al2O3-Ti-Cu system to increase the corrosion resistance of plasma coatings]. Zbirnyk naukovykh prats nitsionalnoho universitetu korableubuduvannіa – Collection of scientific works of the National University of Shipbuilding, (1), 74-81.
Syeliverstov, I.A. (2008). Vpliv parametriv procesu vakuumno-dugovoyi metalizaciyi na yakist poroshkovogo materialu. [Impact of parameters of the vacuum-arc metallization process on the quality of the powder material]. Visnik Hersonskogo nacionalnogo tehnichnogo universitetu – Bulletin of the Kherson National Technical University, 3(32), 142-148.
Solovev, A.A., Sochugov N.S., Oskomov K.V., & Rabotkin S.V. (2009). Issledovanie harakteristik plazmy v nesbalansirovannoj magnetronnoj raspylitelnoj sisteme [Investigation of plasma characteristics in an unbalanced magnetron sputtering system]. Fiz. Plazmy – Plasma Phys, 35(5), 443-452.
Metel, A.S., Bolbukov, V.P., Volosova, M.A., & Grigorev, Yu.A. (2014). Ustrojstvo dlya osazhdeniya tonkih plenok s bombardirovkoj bystrymi atomami argona [Device for deposition of thin films with bombardment with fast argon atoms]. Pribory i tehnika eksperimenta – Instruments and technique of experiment, (3), 114-121.
Danilin, B.S. (1989). Primenenie nizkotemperaturnoj plazmy dlya naneseniya tonkih plenok [Application of low-temperature plasma for application of thin films]. Energoatomizdat.
Ramazanov, K.N., Ishmuhametov, D.Z., & Sadakov, N.S. (2011). Ionnoe azotirovanie v neodnorodnoj plazme tleyushego razryada [ Ion nitriding in an inhomogeneous glow discharge plasma]. Vestnik UGATU – Vestnik UGATU, (3), 67-71.
Shehtman S.R., Budilov V.V., Kireev R.M. (2001). Ispolzovanie razryada s polym katodom dlya obrabotki poverhnosti konstrukcionnyh materialov [Use of a discharge with a hollow cathode for processing the surface of structural materials]. Fizika i himiya obrabotki materialov – Physics and chemistry
of material processing, (2), 31-35.
Bolotov, G.P., Bolotov M.G., & Rudenko M.M. (2014). Keruvannya energetichnimi harakteristikami tliyuchogo rozryadu v umovah difuzijnogo zvaryuvannya. [Control of the energy characteristics of a glow discharge in the conditions of diffusion welding.] Visnik Chernihivskoho derzhavnoho tehnolohichnoho
universitetu. Seriіa: Tehnichni nauki – Bulletin of the Chernihiv State Technological University. Series: Technical sciences, (1(71)), 145-150.
Kotelnikov, D.I. (1985). Fiziko-tehnicheskie i tehnologicheskie processy svarki v tleyushem razryade [Physico-technical and technological processes of welding in a glow discharge]. [Doctor dissertation; MVTU].
Sadovnikov, B.V. (1982). Diffuzionnaya svarka v tleyushem razryade tverdogo splava so stalyu na opytnom obrazce serijnoj ustanovki DS [Diffusion welding in a glow discharge of a hard alloy with steel on a pilot sample of a serial installation of DW]. Elektrotehnicheskaya promyshlennost. Ser. Elektrosvarka
– Electrotechnical industry. Ser. Electric welding, 4, 3-5.
Novik, F.S. (1972). Matematicheskie metody planirovaniya eksperimentov v metallovedenii [Mathematical methods of planning experiments in metallurgy]. MISIS.
Adler, Yu.P., Markova, E.V., & Granovskii, Yu.V. (1976). Planirovanie eksperimenta pri poiske optimalnyh uslovij [Planning the experiment in search of optimal conditions]. Nauka.
Nalimov, V.V. (1971). Teoriia eksperimenta [The theory of experiment]. Nauka.
Bolotov, M.G., & Bolotov G.P. (2020). Usunennya stabilizaciyi elektrichnih dug u procesah zvaryuvannya ta payannya v tliyuchomu rozryadi [Elimination of stabilization of electric arcs in the processes of welding and soldering in glow discharge]. Naukovi visti KPI – Naukovi visti KPI, (3), 50-57.
Diatlov, V.I. (1970). Tehnologiya svarki v tleyushem razryade. Diffuzionnoe soedinenie v vakuume metallov, splavov i nemetallicheskih materialov [Technology of strife in a smoldering discharge. Diffusion joining of metals, alloys and non-metallic materials in a vacuum]. PNILDSV.
Megalingam, M., & Sarma, B. (2019). Occurrence of ionization instability associated with plasma bubble in glow discharge magnetized plasma. Plasma Sci. Technol., 21, 1–22.
Johann Laimer, & Herbert Stori. (2006). Glow Discharges Observed in Capacitive Radio-Frequency Atmospheric-Pressure Plasma Jets. Plasma Process. Polym., 3, 573–586.
Bolotov, M.G., & Bolotov, G.P. (April 2019). Elimination of Electric Arc Stabilization in Precision Welding with High-Current Glow Discharge. 2019 IEEE 39th International Conference on Electronics and Nanotechnology (ELNANO) (pp. 578-583).
Bolotov G.P., Bolotov M.G. (2008) Doslidzhennya stijkosti tliyuchogo rozryadu z porozhnistim katodom v umovah zvaryuvannya [Investigation of the stability of glow discharge with a hollow cathode under welding conditions]. Visnik ChDTU – Bulletin of ChDTU, (36), 100-106.
Bolotov G.P., Bolotov M.G., Stepenko S.A. (2018). The ways of stabilization of high-current glow dischzrge in welding. 2018 IEEE 3rd International Conference on Intelligent Energy and Power Systems (IEPS) (pp.358- 363).
##submission.downloads##
Опубліковано
Як цитувати
Номер
Розділ
Ліцензія
Ця робота ліцензується відповідно до Creative Commons Attribution-NonCommercial 4.0 International License.
