The usage of the elemental base of the vibratory mill with the spatial circulation movement of material to create drying rig

Kaletnik, Hryhorii; Solona, Olena; Kotov, Borys; Stepanenko, Seghii; Shvydia, Viktor; Kalinichenko, Roman; Tverdokhlib, Ihor; Polievoda, Yurii

doi:10.15199/48.2024.03.41

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Tytuł artykułu

The usage of the elemental base of the vibratory mill with the spatial circulation movement of material to create drying rig

Autorzy

Kaletnik Hryhorii , Solona Olena , Kotov Borys , Stepanenko Seghii , Shvydia Viktor , Kalinichenko Roman , Tverdokhlib Ihor , Polievoda Yurii

Treść / Zawartość

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Identyfikatory

DOI

10.15199/48.2024.03.41

Warianty tytułu

Wykorzystanie podstawy elementarnej młyna wibracyjnego z przestrzennym ruchem cyrkulacyjnym materiału do stworzenia suszarki

Języki publikacji

Abstrakty

The analysis of existing vibration rigs revealed that the most promising is the use of vibro-milling chambers with spatial-circulation movement of dispersed material for thermal processing of grain, in particular drying. A mathematical description of the grain drying process and design parameters of the installation have been developed. Using these experimental data, the indicators of the vibrating dryer, that was created on the basis of the grinding chamber of the vibratory mill, were determined.

Analiza istniejących urządzeń wibracyjnych wykazała, że najbardziej obiecujące jest zastosowanie komór wibromielących z przestrzenno-cyrkulacyjnym ruchem materiału rozproszonego do termicznej obróbki ziarna, w szczególności suszenia. Opracowano opis matematyczny procesu suszenia ziarna oraz parametry projektowe instalacji. Wykorzystując te dane doświadczalne wyznaczono wskaźniki suszarki wibracyjnej, która powstała na bazie komory mielenia młyna wibracyjnego.

Słowa kluczowe

drying vibration rig conductive heating grain

suszenie urządzenie wibracyjne próżnia ogrzewanie przewodzące ziarno

Wydawca

Wydawnictwo SIGMA-NOT

Czasopismo

Przegląd Elektrotechniczny

Rocznik

2024

Tom

R. 100, nr 3

Strony

232--237

Opis fizyczny

Bibliogr. 25 poz., rys.

Twórcy

autor

Kaletnik Hryhorii

Academician NAAS of Ukraine, Head of the Department of Administrative Management and Alternative Fuel Resources, Vinnytsia National Agrarian University (21008, 3, Sonyachna str., Vinnytsia, Ukraine)

https://orcid.org/0000-0002-4848-2796

autor

Solona Olena

solona_o_v@ukr.net

Academician NAAS of Ukraine, Head of the Department of Administrative Management and Alternative Fuel Resources, Vinnytsia National Agrarian University (21008, 3, Sonyachna str., Vinnytsia, Ukraine)

https://orcid.org/0000-0002-4596-0449

autor

Kotov Borys

eetsapk@pdatu.edu.u

Podillia State University (32316, 12, Shevchenko Str., Kamianets Podilskyi, Khmelnytskyi region, Ukraine)

https://orcid.org/0000-0001-6369-3025

autor

Stepanenko Seghii

stepanenko_s@ukr.net

National Scientific Center «Institute of Agricultural Mechanization and Electrification» (08631, 11, Vokzalna St, Glevakha, Fastiv district, Kiyv region, Ukraine)

https://orcid.org/0000-0002-8331-4632

autor

Shvydia Viktor

Shvidia@gmail.com

National Scientific Center «Institute of Agricultural Mechanization and Electrification» (08631, 11, Vokzalna St, Glevakha, Fastiv district, Kiyv region, Ukraine)

https://orcid.org/0000-0002-8113-2173

autor

Kalinichenko Roman

rkalinichenko@ukr.net

Nizhyn Agrotechnical Institute, (16600, 10, Shevchenko str., Nizhyn, Ukraine)

https://orcid.org/0000-0001-9325-1551

autor

Tverdokhlib Ihor

igor_tverdokhlib@yahoo.com

Academician NAAS of Ukraine, Head of the Department of Administrative Management and Alternative Fuel Resources, Vinnytsia National Agrarian University (21008, 3, Sonyachna str., Vinnytsia, Ukraine)

https://orcid.org/0000-0003-1350-3232

autor

Polievoda Yurii

vinyura36@gmail.com

Academician NAAS of Ukraine, Head of the Department of Administrative Management and Alternative Fuel Resources, Vinnytsia National Agrarian University (21008, 3, Sonyachna str., Vinnytsia, Ukraine)

https://orcid.org/0000-0002-2485-0611

Bibliografia

[1]. Prysiazhniuk D.V. Analysis of equipment for drying grain raw materials during post-harvest processing. Vibrations in engineering and technology. 86 (2017), nr 3, 136–144.
[2]. Tsurkan O.V., Pryshliak V.M., Prysiazhniuk D.V. Intensification of grain drying in the process of its post-harvest processing. Technology, energy, transport of agricultural industry. 97 (2017), nr 2, 99–103.
[3]. Tsurkan O.V., Polievoda Y.A., Prysyazhnyuk D.V. et al. Vibromechanical intensification of heat and mass transfer processes during grain dehydration: Proceedings of the International Scientific and Technical Conference, 8-10 November (2016), Kyiv, Ukraine, 112–114.
[4]. Paziuk O.D., Palamarchuk I.P., Paziuk V.M. Vibrating grain dryers as a way to intensify and increase the efficiency of grain drying. Vibrations in engineering and technology. 60 (2010), nr 4, 115–122.
[5]. Kaletnyk G.M., Tsurkan O.V. Features of the design of vibration equipment for drying high-moisture seed raw materials. Vibrations in engineering and technology. 100 (2021), nr 1, 5– 12. https://doi.org/10.37128/2306-8744-2021-1-1
[6]. Paziuk V.M., Paziuk O.D., Romanenko O.D. Energy-saving modes of drying seed grain and their implementation in a vibratory grain dryer. Vibrations in engineering and technology. 83 (2016), nr 3, 202–207.
[7]. Zozulyak I.A. Substantiation of the parameters of drying sunflower grain in vibratory machines with a U-type container: PhD thesis. Vinnytsia (2015) 22 p.
[8]. Palamarchuk I.P., Bandura V.M., Palamarchuk V.I. Substantiation of the design of the conveyor vibrating dryer. Vibrations in engineering and technology. 66 (2012), nr 2, 116– 128.
[9]. Solona O.V. Vibrating machines with spatial-circulating motion of loading for fine grinding of bulk materials (monograph). Vinnytsia: RVV VDAU (2008), 133 p.
[10]. Solona O.V., Bilyk D.A. Vibratory mills for grinding bulk materials of agricultural production. Vibrations in engineering and technology. 70 (2013), nr 2, 196–199.
[11]. Denisov, P.D.; Bernik, P.E.; Solona, O.V. Study of the behavior of loading in the coupled grinding chambers of continuously operating vibratory mills. Mechanical engineering. 30 (1999), nr. 12, 44–51.
[12]. Chubyk R.V., Zozulyak I.A., Bandura V.M. Electromechanical model of an adaptive resonant two-container vibrating dryer. Vibrations in engineering and technology. 63 (2012), nr 1, 128– 134.
[13]. Kotov B.I., Lysenko, V.P., Komarchuk D.S. Mathematical modeling of thermal processes of a press extruder with induction heating. Scientific Bulletin of NUBiP of Ukraine. 166 (2011), nr 4, 113–118.
[14]. Shvydia V.O. Theoretical substantiation of the use of contact heating for drying seeds in a vacuum. Mechanization and Electrification of Agriculture. 103 (2019), nr 10, 67–74.
[15]. Kotov B.I., Shvydia V.O., Pantsyr Y.I., Gerasymchuk I.D. Mathematical modeling of dynamic modes of a grain dryer with induction energy supply. Engineering, energy, transport AIC. 104 (2019), nr 1, 64–70. https://doi.org/10.37128/2520-6168- 2019-1-8
[16]. Adamchuk V.V., Shvydia V.O. Mathematical model of seed heating by mixing in the drum of a vacuum seed dryer // Mechanization and Electrification of Agriculture. 112 (2021), nr 13, 89–96. https://doi.org/10.37204/0131-2189-2021-13-9
[17]. Krischer O. Die Wissenschaftichen GrundPagen der Trocknungstechnik. Berlin-Göttingen-Heldeeberg. (1956) 337 p.
[18]. Tsurkan O.V. Vibromechanical intensification of drying of seeds of tower crops in the process of post-harvest processing: PhD thesis. Hlevakha (2020) 40 p.
[19]. Kotov B.I., Kalinichenko R.A., Lipunov M.I. Analytical determination of dynamic thermal and humidity regimes of continuous grain dryers. Design, production and operation of agricultural machinery. 42 (2012), nr 2, 17–23.
[20]. Shvydia V.O., Aneliak M.M., Stepanenko S.P. Experimental studies of grain seed drying modes with high humidity in a low pressure environment. Mechanization and electrification of agriculture: a national collection. 107 (2019), nr 8, 89–96.
[21]. Kotov B., Spirin A., Tverdokhlib I., Polyevoda Y. Theoretical researches on cooling process regularity of the grain material in the layer. INMATEH – Agricultural Engineering. 54 (2018), nr 1, 87–94.
[22]. Kotov B., Spirin A., Kalinichenko R., Bandura V., Polievoda Y., Tverdokhlib I. Determination the parameters and modes of new heliocollectors constructions work for drying grain and vegetable raw material by active ventilation. Research in Agricultural Engineering. 65 (2019), nr 1, 20–24. https://doi.org/10.17221/73/2017-RAE
[23]. Paziuk V., Petrova Z., Tokarchuk O., Polievoda Y. Special aspects of soybean drying with high seedling vigor. Scientific bulletin, Series D: Mechanical Engineering. 83 (2021), nr 2, 327–336.
[24]. Spirin A., Kupchuk I., Tverdokhlib I., Polievoda Y., Kovalova K., Dmytrenko V. Substantiation of modes of drying alfalfa pulp by active ventilation in a laboratory electric dryer. Przegląd elektrotechniczny. 98 (2022), nr 5, 11–15. https://doi.org/10.15199/48.2022.05.02
[25]. Tsurkan O., Prysiazhniuk Y., Spirin A., Borysiuk D., Tverdokhlib I., Polievoda Y. Research of the process of vibroozone drying of grain. Przegląd elektrotechniczny. 98 (2022), nr 12, 329–333. https://doi.org/10.15199/48.2022.12.76

Uwagi

Opracowanie rekordu ze środków MNiSW, umowa nr POPUL/SP/0154/2024/02 w ramach programu "Społeczna odpowiedzialność nauki II" - moduł: Popularyzacja nauki i promocja sportu (2025).

Typ dokumentu

Bibliografia

Identyfikator YADDA

bwmeta1.element.baztech-95463b11-d141-4eef-9dbf-e8a34d1af395