Machinery & Energetics

Improving energy efficiency of double-disc coulters using boundary estimation method of seed furrow profile influence

Stanislav Nikolayenko, Gennadii Virchenko, Mykola Volokha, Oleksii Vorobiov, Yuliia Lazarchuk-Vorobiova
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Abstract

The relevance of this study lies in the global demand to increase the energy efficiency of agricultural implements while maintaining high agronomic performance. The purpose of the article was to analytically assess the effect of furrow profile parameters on the operational energy performance of tillage tools, using double-disc openers as an example. The methodology was based on geometric modelling of the working components of the coulter in a Cartesian coordinate system, derivation of parametric equations for furrow contours, and analytical calculation of the furrow cross-sectional area depending on tillage depth, disc diameter, and disc alignment angles. The study demonstrated that the furrow area for discs with a 350 mm diameter increased from 415 mm² to 4106 mm² as the tillage depth rose from 20 mm to 80 mm. With a fixed depth of 50 mm and angles α =50°, β =20°, the furrow area varied from 1762 mm² to 1935 mm² as the disc diameter changed from 300 mm to 400 mm. A quadratic approximation formula was proposed to express this dependence. The results showed that reducing the tillage depth from 50 mm to 45 mm led to a decrease in furrow area from 1851 mm² to 1277 mm², while increasing the depth to 55 mm resulted in an increase to 2516 mm². The influence of disc inclination angles on the cross-sectional area was also demonstrated: decreasing the angles to α=40° and β=15° reduced the area to 1522 mm². The proposed approach enabled further configuration optimisation of coulters under real conditions. The methodology presented in this publication makes it possible to determine the most rational configuration of tillage tools for the existing circumstances through appropriate analysis

Keywords

energy efficiency of agricultural machinery, disc tillage tools, mathematical modelling, computer-aided design, computer information technology

Suggested citation
Nikolayenko, S., Virchenko, G., Volokha, M., Vorobiov, O., & Lazarchuk-Vorobiova, Yu. (2025). Improving energy efficiency of double-disc coulters using boundary estimation method of seed furrow profile influence. Machinery & Energetics, 16(3), 20-32. https://doi.org/10.31548/machinery/3.2025.20
References
  1. Ahmad, F., Qiu, B., Ding, O., Ding, W., Khan, Z., Shoaib, M., Chandio, F., Rehim, A., & Khaliq, A. (2020). Discrete element method simulation of disc type furrow openers in paddy soil. International Journal of Agricultural and Biological Engineering, 13(4), 103-110. doi: 10.25165/j.ijabe.20201304.4800.
  2. Aikins, K., Barr, J., Ucgul, M., Jensen, T., Antille, D., & Desbiolles, J. (2020). No tillage furrow opener performance: A review of tool geometry, settings and interactions with soil and crop residue. Soil Research, 58(7), 603-621. doi: 10.1071/SR19153.
  3. Chandio, F., Li, Y., Xu, L., Ma, Z., Ahmad, F., Cuong, D., & Lakhiar, I. (2020). Predicting 3D forces of disc tool and soil disturbance area using fuzzy logic model under sensor-based soil-bin. International Journal of Agricultural and Biological Engineering, 13(4), 77-84. doi: 10.25165/j.ijabe.20201304.5115.
  4. Damanauskas, V., & Janulevičius, A. (2022). Effect of tillage implement (spring tine cultivator, disc harrow), soil texture, forward speed, and tillage depth on fuel consumption and tillage quality. Journal of Agricultural Engineering, 53(3), article number 1371. doi: 10.4081/jae.2022.
  5. Hamid, A., & Alsabbagh, A. (2023). Effect of Moldboard types, Two depths of tillage and two speeds of tractor in some physical properties and pulverisation of soil. Kufa Journal for Agricultural Sciences, 15(1), 105-116. doi: 10.36077/kjas/2023/v15i1.10334.
  6. Karayel, D., Jotautiene, E., & Šarauskis, E. (2024). the effect of furrow opener and disc coulter configurations on seeding performance under different residue cover densities. AgriEngineering, 6(2), 1277-1288. doi: 10.3390/agriengineering6020073.
  7. Kumar, N., Sawant, C., Sharma, R., Chhokar, R., Tiwari, P., Singh, D., Roul, A., Tripathi, S., Gill, S., & Singh, G. (2021). Combined effect of disc coulters and operational speeds on soil disturbance and crop residue cutting under no-tillage system in soil bin. Journal of Scientific & Industrial Research, 80(9), 739-749. doi: 10.56042/jsir.v80i09.40333.
  8. Malasli, M., & Çelik, A. (2023). Effects of the disc and tilt angle of a single disc-type furrow opener of a no-till seeder on residue distribution and the furrow profile. Turkish Journal of Agriculture and Forestry, 47(6), article number 19. doi: 10.55730/1300-011X.3146.
  9. Nikolaenko, S., Bondar, M., Bulgakova, O., Vasileva, V., & Vartukapteinis, K. (2021). Studying requirements for substantial list of professional knowledge for students of agricultural engineering specialities. In 20th international scientific conference: Engineering for rural development (pp. 1519-1525). Jelgava: Latvia University of Life Sciences and Technologies. doi: 10.22616/ERDev.2021.20.
  10. Parihar, D., Dogra, B., & Narang, M. (2023). Performance evaluation of different furrow openers for sustainable tillage: A review. Indian Journal of Ecology, 50(4), 1133-1142. doi: 10.55362/IJE/2023/4025.
  11. Pavlova, Ya., & Litvinov, D. (2024). The influence of previous crops and tillage on available moisture reserves of chernozem typical for growing spring barley. Plant and Soil Science, 15(2), 32-41. doi: 10.31548/plant2.2024.32.
  12. Ranta, O., Gheţe, A., Stănilă, S., Muntean, M., Marian, O., & Molnar-Irimie, A. (2021). Influence of design of the disc furrow opener of no-till sowing machines on the seedbed quality. Romanian Agricultural Research, 38, 239-249. doi: 10.59665/rar3826.
  13. Rosu, B., Voicu, G., Constantin, G., Tudor, P., & Stefan, E. (2024). Aspects regarding the physical parameters and wear in the work process of the disc openers for seeding machines. Agriculture, 14(7), article number 1066. doi: 10.3390/agriculture14071066.
  14. Sadek, M., Chen, Y., & Zeng, Z. (2021). Draft force prediction for a high-speed disc implement using discrete element modelling. Biosystems Engineering, 202, 133-141. doi: 10.1016/j.biosystemseng.2020.12.009.
  15. Sugirbay, A., et al. (2023). Double disc colter for a no-till seeder simultaneously applying granular fertilisers and wheat seeds. Agriculture, 13(5), article number 1102. doi: 10.3390/agriculture13051102.
  16. Vorobiov, O. (2024). Computer modelling of basic design and operational geometrical parameters of double disc coulters. Bulletin of Sumy National Agrarian UniversityThe Series: Mechanisation and Automation of Production Processes, 4(58), 12-20. doi: 10.32782/msnau.2024.4.
  17. Xu, G., Xie, Y., Peng, S., Liang, L., & Ding, Q. (2023). Performance evaluation of vertical discs and disc coulters for conservation tillage in an intensive rice-wheat rotation system. Agronomy, 13(5), article number 1336. doi: 10.3390/agronomy13051336.
  18. Yablonskyi, P., Rogovskii, I., Sobczuk, H., Virchenko, G., Volokha, M., & Vorobiov, O. (2024). Computational approach to geometric modelling of plough bodies. Journal of Engineering Sciences, 11(1), E9-E18. doi: 10.21272/jes.2024.11(1).e2.
  19. Yablonskyi, P., Rogovskii, I., Virchenko, G., Borek, K., Volokha, M., & Golova, O. (2025). Geometric modelling of disc furrow profile. Journal of Engineering Sciences, 12(1), E1-E8. doi: 10.21272/jes.2025.12(1).e1.
  20. Zeng, Z., Thoms, D., Chen, Y., & Ma, X. (2021). Comparison of soil and corn residue cutting performance of different discs used for vertical tillage. Scientific Reports, 11, article number 2537. doi: 10.1038/s41598-021-82270-9.