Experimental substantiation of the rational parameters for a reaping machine of the comb type for harvesting oil flax seeds

Authors

  • Olecsiy Kozachenko Kharkiv Petro Vasylenko National Technical University of Agriculture Alchevskykh str., 44, Kharkiv, Ukraine, 61002, Ukraine https://orcid.org/0000-0001-5139-6138
  • Andrii Pakhuchyi Kharkiv national agrarian University named after V. V. Dokuchaev p/o “Dokuchaevske-2”, Kharkiv dist., Kharkiv reg., Ukraine, 62483, Ukraine https://orcid.org/0000-0002-7371-5264
  • Olexander Shkregal Kharkiv Petro Vasylenko National Technical University of Agriculture Alchevskykh str., 44, Kharkiv, Ukraine, 61002, Ukraine https://orcid.org/0000-0002-5552-9679
  • Sergiy Sorokin Kharkiv Petro Vasylenko National Technical University of Agriculture Alchevskykh str., 44, Kharkiv, Ukraine, 61002, Ukraine
  • Sergey Dyakonov Kharkiv national agrarian University named after V. V. Dokuchaev p/o “Dokuchaevske-2”, Kharkiv dist., Kharkiv reg., Ukraine, 62483, Ukraine https://orcid.org/0000-0002-2451-5610
  • Мykola Gusarenko Kharkiv national agrarian University named after V. V. Dokuchaev p/o “Dokuchaevske-2”, Kharkiv dist., Kharkiv reg., Ukraine, 62483, Ukraine https://orcid.org/0000-0001-8689-3855
  • Volodymyr Kadenko Kharkiv Petro Vasylenko National Technical University of Agriculture Alchevskykh str., 44, Kharkiv, Ukraine, 61002, Ukraine https://orcid.org/0000-0002-3095-3633

DOI:

https://doi.org/10.15587/1729-4061.2020.212733

Keywords:

combing reaping machine, technology of combing plants on the root, oil flax, optimal structural-mode parameters

Abstract

This paper reports the results of the experimental study to substantiate the rational structural and regime parameters of a two-drum reaping machine for harvesting flax oilseeds by the method of combing plants on the root. We have confirmed the results of the preliminary mathematical modeling of the process of separating a combed heap in the reaping machine with a predefined curved shape of the casing.

An experimental study of the heap separation process in a reaping machine has established the dependence of the mass fraction of the discharge of husk and stem particles from its region δh, the proportion of the release of seeds and capsules with seeds δh, and the consumed power P, on the rotation frequency of the beater-reflector n1, and the combing drum n2, the position of the air grate L and its width B. The following structural-mode parameters of the comb-type reaping machine for harvesting oil flax seeds have been defined as the most significant ones: the rotation frequency of the beater-reflector, n1=892 rpm; the rotation frequency of the comb drum, n2=652 rpm; the position of the air grate, L=0.62 m, and its width, B=0.56 m. In this case, the mass fraction of the discharge of husk and stem particles is δh=47.5 %, the share of the loss of seeds and capsules with seeds from the reaping machine is, respectively, δh=2.1 %, and the power consumed to perform the process is P=2.7 kW.

The statistical analysis has demonstrated that the correlation coefficient between the theoretical and experimental data is 0.88‒0.95; a relative error in the optimal values is 4.6 %. The actual and statistical comparison of the theoretical and experimental data has confirmed the adequacy of the mathematical models built as a result of the theoretical research.

Based on the results of our experimental research, one can argue about the usefulness of their application for engineering calculations when designing new technical means for harvesting crops by the method of combing plants on the root

Author Biographies

Olecsiy Kozachenko, Kharkiv Petro Vasylenko National Technical University of Agriculture Alchevskykh str., 44, Kharkiv, Ukraine, 61002

Doctor of Technical Sciences, Professor

Department of Reliability, Durability and Technical Service of Machines named after V. Ya. Anilovich

Andrii Pakhuchyi, Kharkiv national agrarian University named after V. V. Dokuchaev p/o “Dokuchaevske-2”, Kharkiv dist., Kharkiv reg., Ukraine, 62483

PhD, Senior Lecturer

Department of Technical Support of Agricultural Production

Olexander Shkregal, Kharkiv Petro Vasylenko National Technical University of Agriculture Alchevskykh str., 44, Kharkiv, Ukraine, 61002

PhD, Associate Professor

Department of Reliability, Durability and Technical Service of Machines named after V. Ya. Anilovich

Sergiy Sorokin, Kharkiv Petro Vasylenko National Technical University of Agriculture Alchevskykh str., 44, Kharkiv, Ukraine, 61002

PhD, Associate Professor

Department of Reliability, Durability and Technical Service of Machines named after V. Ya. Anilovich

Sergey Dyakonov, Kharkiv national agrarian University named after V. V. Dokuchaev p/o “Dokuchaevske-2”, Kharkiv dist., Kharkiv reg., Ukraine, 62483

PhD, Associate Professor

Department of Technical Support of Agricultural Production

Мykola Gusarenko, Kharkiv national agrarian University named after V. V. Dokuchaev p/o “Dokuchaevske-2”, Kharkiv dist., Kharkiv reg., Ukraine, 62483

PhD, Associate Professor

Department of Technical Support of Agricultural Production

Volodymyr Kadenko, Kharkiv Petro Vasylenko National Technical University of Agriculture Alchevskykh str., 44, Kharkiv, Ukraine, 61002

PhD

Department of Reliability, Durability and Technical Service of Machines named after V. Ya. Anilovich

References

  1. Kushnarev, A. Kravchuk, V., Lezhenkin, A. (2010). Problemy sovershenstvovaniya tehnologii uborki zernovyh. Tekhnika i tekhnolohiyi APK, 2, 6–12.
  2. Sysolin, P. V., Ivanenko, I. (2008). Problemy i perspektivy vnedreniya v Ukraine tehnologii uborki zernovyh kolosovyh kul'tur metodom ochesyvaniya koloskov. Tehnika APK, 5, 24–29.
  3. Lezhenkin, A. N., Kravchuk, V. I., Kushnarev, A. S. (2010). Tehnologiya uborki zernovyh metodom ochesa rasteniy na kornyu: sostoyanie i perspektivy. Bila Tserkva, 400.
  4. Yuan, J., Lan, Y. (2007). Development of an Improved Cereal Stripping Harvester. Agricultural Engineering International: the CIGR Ejournal, IX. Available at: http://citeseerx.ist.psu.edu/viewdoc/download?doi=10.1.1.504.7187&rep=rep1&type=pdf
  5. Chekhov, A. V., Lapa, O. M., Mishchenko, L. Yu., Poliakova, I. O. (2007). Lon oliynyi: biolohiya, sorty, tekhnolohiya vyroshchuvannia. Kyiv: Ukrainska akademiya ahrarnykh nauk, Instytut oliynykh kultur, 59.
  6. Sai, V. A. (2012). Tekhnolohiya vyroshchuvannia, zbyrannia ta pervynnoi pererobky lonu oliynoho. Lutsk: LNTU, 166.
  7. Shabanov, P. A., Shabanov, N. P. (2004). Sravnitel'nyy analiz odno- i dvuhbarabannyh ochesyvayushchih ustroystv na uborke zernovyh kul'tur. Nauchnye trudy Ukrainskogo tsentra ispytaniy tehniki (UKRTSIT). Doslidnitskoe, 173.
  8. Shabanov, P. A., Shabanov, N. P. (2006). Obmolot na kornyu – dal'neyshee razvitie dvuhfaznogo sposoba obmolota zernovyh kul'tur. Dostizheniya nauki i tehniki APK, 8, 8–10.
  9. Golubev, I. K., Goncharov, B. I., Shabanov, P. A. (1986). Obmolot risa na kornyu dvuhbarabannym ochesyvayushchim ustroystvom. Traktory i sel'skohozyaystvennye mashiny, 2, 35–38.
  10. Kozachenko, O. V., Diakonov, S. O., Pakhuchyi, A. M. (2018). Obgruntuvannia formy obtikacha obchisuvalnoi zhnyvarky dlia zbyrannia lonu oliinoho. Mekhanizatsiya ta avtomatyzatsiya vyrobnychykh protsesiv, 5 (33), 48–52.
  11. Kozachenko, O. V., Diakonov, S. O., Honcharov, V. V., Pakhuchyi, A. M. (2019). Doslidzhennia rezhymnykh parametriv obchisuvalnoho barabanu zhnyvarky. Visnyk Kharkivskoho natsionalnoho tekhnichnoho universytetu silskoho hospodarstva imeni Petra Vasylenka, 199, 388–396.
  12. Kozachenko, O., Pahuchiy, А. (2019). Modeling of interaction with plants linseed occupancy drum. TEKA. An International Quarterly Journal on Motorization, Vehicle Operation, Energy Efficiency and Mechanical Engineering. Lublin-Rzeszow, 19 (1), 59–64.
  13. Kozachenko, O. V., Pakhuchy, A. M., Dyakonov, S. O., Goncharo, V. V. (2019). Substantiation of structural and technological parameters of the reeling drum. Engineering of nature management, 1 (11), 74–82.
  14. Kozachenko, O., Pakhuchyi, A., Shkregal, O., Dyakonov, S., Blaznyuk, O., Kadenko, V. (2019). Results of numerical modeling of the process of harvesting the seeds of flax by a harvester of the stripping type. Eastern-European Journal of Enterprise Technologies, 3 (1 (99)), 66–74. doi: https://doi.org/10.15587/1729-4061.2019.169664
  15. Bai, C., Gosman, A. D. (1995). Development of Methodology for Spray Impingement Simulation. SAE Technical Paper Series. doi: https://doi.org/10.4271/950283
  16. Wallin, S. (2000). Engineering turbulence modelling for CFD with a focus on explicit algebraic Reynolds stress models. Stockholm, 254.
  17. Aliev, E. B., Bandura, V. M., Pryshliak, V. M., Yaropud, V. M., Trukhanska, O. O. (2018). Modeling of mechanical and technological processes of the agricultural industry. INMATEH – Agricultural Engineering, 54 (1), 95–104.
  18. Bhanage, G. B., Shahare, P. U., Aware, V. V., Dhandeand, K. G., Deshmukh, P. S. (2017). Development of stripper harvester for paddy. Journal of Applied and Natural Science, 9 (4), 1943–1948. doi: https://doi.org/10.31018/jans.v9i4.1469
  19. Kozachenko, O. V. (2018). Pat. No. 135514 UA. Laboratorna ustanovka dlia doslidzhennia parametriv i rezhymiv protsesu obchisuvannia silskohospodarskykh kultur. No. u201811954; declareted: 03.12.2018; published: 10.07.2019, Bul. No. 13.

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Published

2020-10-31

How to Cite

Kozachenko, O., Pakhuchyi, A., Shkregal, O., Sorokin, S., Dyakonov, S., Gusarenko М., & Kadenko, V. (2020). Experimental substantiation of the rational parameters for a reaping machine of the comb type for harvesting oil flax seeds. Eastern-European Journal of Enterprise Technologies, 5(1 (107), 52–59. https://doi.org/10.15587/1729-4061.2020.212733

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Section

Engineering technological systems