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Theoretical studies of the technological process of harvesting chicory root crops
Назва | Theoretical studies of the technological process of harvesting chicory root crops |
Назва англійською | Theoretical studies of the technological process of harvesting chicory root crops |
Автори | Mykola Pidgurskyi, Halina Gerasymchuk, Maria Pankiv |
Принадлежність | Ternopil Ivan Puluj National Technical University, Ternopil, Ukraine
Lutsk National Technical University, Lutsk, Ukraine |
Бібліографічний опис | Theoretical studies of the technological process of harvesting chicory root crops / Mykola Pidgurskyi, Halina Gerasymchuk, Maria Pankiv // Scientific Journal of TNTU. — Tern.: TNTU, 2023. — Vol 111. — No 3. — P. 139–151. |
Bibliographic description: | Pidgurskyi M., Gerasymchuk H., Pankiv M. (2023) Theoretical studies of the technological process of harvesting chicory root crops. Scientific Journal of TNTU (Tern.), vol 111, no 3, pp. 139–151. |
DOI: | https://doi.org/10.33108/visnyk_tntu2023.03.139 |
УДК |
631.361.2 |
Ключові слова |
chicory roots, process, slicing of ghee, impurities, remains of ghee, spherical disc, cleaning shaft, model, second feed. |
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The decrease in the production of chicory root crops, which are valuable raw materials for the production of various products, is restrained by the low level of mechanization of their harvesting processes and unsatisfactory indicators of losses and contamination by impurity components. The purpose of the work: reduction of the second supply of impurities during the collection of chicory roots due to the development and analysis of analytical dependencies that functionally describe the process of collection of chicory roots by the working bodies of a combined single-disc digger. Based on the analysis of graphical dependencies, it was established that: the second supply of general impurities varies from 5 to 18 kg/s; second supply of loose soil – in the range from 4 to 15 kg/s; second supply of vegetable additives - from 0.06 to 0.1 kg/s. The obtained mathematical models are the initial dependencies for further substantiation of the parameters and modes of operation of the transport and cleaning working bodies of the root-harvesting machines. |
ISSN: | 2522-4433 |
Перелік літератури |
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2. Berezhenko E. Experimental research of the module for gathering plant of chicory roots. Scientific Journal of the Ternopil National Technical University. 2021. Vol. 1 (101). P. 56–67.
3. Mou X. Kinematic analysis and experiments of elastic dentations in process of sugarcane leaf sheath stripping, Agricultural Mechanics Report. Journal of Shandong Agricultural University. 2014. Vol 2. P. 122–129.
4. Baranovsky V., Potapenko M. Theoretical analysis of the technological feed of lifted root crops. INMATEH – Agricultural Engineering. 2017. Vol. 51. No. 1. 2017. P. 29–38.
5. Baranovsky V. et al. Results of the experimental investigations of fodder beets harvesting technologies. Scientific journal of TNTU. 2022. Vol. 105. No. 2. P. 6–16.
6. Manjula E. V. PJ. A review of CFD modelling studies on pneumatic conveying and challenges in modelling offshore drill cuttings transport. Powder Technology. 2017. No. 305. P. 782–793.
7. Baranovsky V., Dubchak N., Pankiv M. Experimental research of stripping the leaves from root crops. Acta Technologica Agriculturae. 2017. Vol. 20. No. 3. P. 69–73. Doi: https://doi.org/10.1515/ata-2017-0014.
8. Hevko R. B et al. Development of design and investigation of operation processes of small-scale root crop and potato harvesters. INMATEH – Agricultural Engineering. 2016. Vol. 49. No. 2. P. 53–60.
9. Hevko R. B et al. Mathematical model of a root harvester after-cleaning system. Bulletin of Karaganda University. 2017. Vol. 96. No. 4. P. 81–89. Doi: https://doi.org/10.31489/2019M4/81-89.
10. Jobbágy J., Gabaj D., Árvay J. Evaluation of selected agro-physical properties of a root vegetable. Acta Technologica Agriculturae. 2011. Vol. 14. No. 3. P. 61–65.
11. Júnnyor W. D. SG. et al. Conservation systems change soil resistance to compaction caused by mechanised harvesting. Industrial Crops and Products. 2022. No. 177. 114532. Doi: https://doi.org/ 10.1016/j.indcrop.2022.114532.
12. Lord R. A. Reed canarygrass (Phalaris arundinacea) outperforms Miscanthus or willow on marginal soils, brownfield and non-agricultural sites for local, sustainable energy crop production. Biomass Bioenergy. 2015. No. 78. P. 110–125. Doi: https://doi.org/10.1016/j.biombioe.2015.04.015.
13. Mileusnić Z. I. et al. Soil compaction due to agricultural machinery impact. Journal of Terramechanics. 2022. No. 100. P. 51–60. Doi: https://doi.org/10.1016/j.jterra.2021.12.002.
14. Sauro J., Lewis J. R. Quantifying the User Experience: Practical Statistics for User Research. 2 nd edition. US : Morgan Kaufmann. 2013. ISBN-13: 978-0128023082.
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16. Zhu B. et al. Planosol soil conditions improved with four- kinds of ploughs, Part 2: Soybean field in State Farm 854, J. JSAM-Hokkaido. 2017. No. 57. P. 11–16.
17. Araya K. Soil failure caused by subsoilers with pressurized water injection. J. Research in Agriculture Engineering. 1994. No. 58. P. 79–87.
18. Jia H. et al. Improvement of planosol solum: Part 8: Analysis of draught of a Three-stage Subsoil Mixing Plough. J. Research in Agriculture Engineering. 1998. No. 70. P. 85–93.
19. Kuroyanagi N. et al. Effect of long-term application of organic matters on upland field. (2) yield of upland crop and physical properties of soil, (Fukuoka Agricultural Research Center, Chikushino, Fukuoka 818 Japan) Bull. Fukuoka Agricul. Res. Center. 1997. No. 16. P. 63–66.
20. Skalický J. Research of sugar-beet tubers mechanical properties. Research in Agriculture Engineering. 2003. Vol. 49. No. 3. P. 80–84. Doi: https://doi.org/10.17221/4956-RAE.
21. Karwowski T. Pure agricultural machinery technology. Theory and construction of agricultural machines. Root crop harvesting machines. Berlin. 1974.
22. Herasymchuk Н. А. et al. Analytical research results of the combined root digger. INMATEH – Agricultural Engineering. 2018. Vol. 54. No. 1. P. 63–72.
23. Frey S., Dadalau A., Verl A. Expedient modeling of ball screw feed drives. Production Engineering. 2012. Vol. 6 (2). P. 205–211.
24. Ziegler K. Trends in sugar beet harvesting technology. Agritechnika. 2019. No. 59. P. 48–57.
25. Hoffmann C. et al. Importance of harvesting system and variety for storage losses of sugar beet. Sugar Industry. 2018. Vol. 143 (8). P. 474–486.
26. Storozhuk I. M., Pankiv V. R. Research results of harvesting haulm remnants of root crops. INMATEH – Agricultural Engineering. 2015. Vol. 46. No. 2. Р. 101–108.
27. Pankiv M. et al. Method of step-by-step development of a mathematical model of the process of separating impurities from root crops. Scientific Journal of TNTU. 2021. Vol. 104. No. 4. P. 74–86. |
References: |
1. Pankiv М. Modeling of the technological functioning process transport and cleaning system of roots. Innovative solutions in modern science. 2019.Vol. 9 (36). P. 50–60.
2. Berezhenko E. Experimental research of the module for gathering plant of chicory roots. Scientific Journal of the Ternopil National Technical University. 2021. Vol. 1 (101). P. 56–67.
3. Mou X. Kinematic analysis and experiments of elastic dentations in process of sugarcane leaf sheath stripping, Agricultural Mechanics Report. Journal of Shandong Agricultural University. 2014. Vol 2. P. 122–129.
4. Baranovsky V., Potapenko M. Theoretical analysis of the technological feed of lifted root crops. INMATEH – Agricultural Engineering. 2017. Vol. 51. No. 1. 2017. P. 29–38.
5. Baranovsky V. et al. Results of the experimental investigations of fodder beets harvesting technologies. Scientific journal of TNTU. 2022. Vol. 105. No. 2. P. 6–16.
6. Manjula E. V. PJ. A review of CFD modelling studies on pneumatic conveying and challenges in modelling offshore drill cuttings transport. Powder Technology. 2017. No. 305. P. 782–793.
7. Baranovsky V., Dubchak N., Pankiv M. Experimental research of stripping the leaves from root crops. Acta Technologica Agriculturae. 2017. Vol. 20. No. 3. P. 69–73. Doi: https://doi.org/10.1515/ata-2017-0014.
8. Hevko R. B et al. Development of design and investigation of operation processes of small-scale root crop and potato harvesters. INMATEH – Agricultural Engineering. 2016. Vol. 49. No. 2. P. 53–60.
9. Hevko R. B et al. Mathematical model of a root harvester after-cleaning system. Bulletin of Karaganda University. 2017. Vol. 96. No. 4. P. 81–89. Doi: https://doi.org/10.31489/2019M4/81-89.
10. Jobbágy J., Gabaj D., Árvay J. Evaluation of selected agro-physical properties of a root vegetable. Acta Technologica Agriculturae. 2011. Vol. 14. No. 3. P. 61–65.
11. Júnnyor W. D. SG. et al. Conservation systems change soil resistance to compaction caused by mechanised harvesting. Industrial Crops and Products. 2022. No. 177. 114532. Doi: https://doi.org/ 10.1016/j.indcrop.2022.114532.
12. Lord R. A. Reed canarygrass (Phalaris arundinacea) outperforms Miscanthus or willow on marginal soils, brownfield and non-agricultural sites for local, sustainable energy crop production. Biomass Bioenergy. 2015. No. 78. P. 110–125. Doi: https://doi.org/10.1016/j.biombioe.2015.04.015.
13. Mileusnić Z. I. et al. Soil compaction due to agricultural machinery impact. Journal of Terramechanics. 2022. No. 100. P. 51–60. Doi: https://doi.org/10.1016/j.jterra.2021.12.002.
14. Sauro J., Lewis J. R. Quantifying the User Experience: Practical Statistics for User Research. 2 nd edition. US : Morgan Kaufmann. 2013. ISBN-13: 978-0128023082.
15. Špokas L et al. The experimental research of combine harvesters. Research in Agriculture Engineering. 2016. Vol. 62. No. 3. P. 106–112. Doi: https://doi.org/10.17221/16/2015-RAE.
16. Zhu B. et al. Planosol soil conditions improved with four- kinds of ploughs, Part 2: Soybean field in State Farm 854, J. JSAM-Hokkaido. 2017. No. 57. P. 11–16.
17. Araya K. Soil failure caused by subsoilers with pressurized water injection. J. Research in Agriculture Engineering. 1994. No. 58. P. 79–87.
18. Jia H. et al. Improvement of planosol solum: Part 8: Analysis of draught of a Three-stage Subsoil Mixing Plough. J. Research in Agriculture Engineering. 1998. No. 70. P. 85–93.
19. Kuroyanagi N. et al. Effect of long-term application of organic matters on upland field. (2) yield of upland crop and physical properties of soil, (Fukuoka Agricultural Research Center, Chikushino, Fukuoka 818 Japan) Bull. Fukuoka Agricul. Res. Center. 1997. No. 16. P. 63–66.
20. Skalický J. Research of sugar-beet tubers mechanical properties. Research in Agriculture Engineering. 2003. Vol. 49. No. 3. P. 80–84. Doi: https://doi.org/10.17221/4956-RAE.
21. Karwowski T. Pure agricultural machinery technology. Theory and construction of agricultural machines. Root crop harvesting machines. Berlin. 1974.
22. Herasymchuk Н. А. et al. Analytical research results of the combined root digger. INMATEH – Agricultural Engineering. 2018. Vol. 54. No. 1. P. 63–72.
23. Frey S., Dadalau A., Verl A. Expedient modeling of ball screw feed drives. Production Engineering. 2012. Vol. 6 (2). P. 205–211.
24. Ziegler K. Trends in sugar beet harvesting technology. Agritechnika. 2019. No. 59. P. 48–57.
25. Hoffmann C. et al. Importance of harvesting system and variety for storage losses of sugar beet. Sugar Industry. 2018. Vol. 143 (8). P. 474–486.
26. Storozhuk I. M., Pankiv V. R. Research results of harvesting haulm remnants of root crops. INMATEH – Agricultural Engineering. 2015. Vol. 46. No. 2. Р. 101–108.
27. Pankiv M. et al. Method of step-by-step development of a mathematical model of the process of separating impurities from root crops. Scientific Journal of TNTU. 2021. Vol. 104. No. 4. P. 74–86 |
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