The results of root crop cleaner experimental research

Harvesting root crops, such as large sugar and fodder beetroots, and long-term chicory roots is a technologically complex and ambiguous technological process. It consists of different structural successive technological operations of pruning, digging roots, cleaning the dug heap from impurities, loading clean roots into the hopper or in vehicles moving near the root harvester. The aim of the study is to increase the efficiency of the process of harvesting roots by analyzing existing approaches to mathematical simulation of the technological process of separating impurities from roots. The developed mathematical model allows describing at the highest-level more precisely the process of gradual separation of variously structured components of impurities from root crops by each cleaning working body, which are constituent units of technical systems of root-harvesting machines. The proposed mathematical model can be used to optimize the parameters of the working bodies and other processes, in particular for the separation of the harvested grain heap, preparatory processes of seed, and so on.

Method of step-by-step development of a mathematical model of the process of separating impurities from root crops

Pankiv,

Pidhurskyi,

Pylypets

et al. 2021

Methodology for refining the performance of screw conveyor

Pankiv¹,

Pylypets²,

Pankiv³

et al. 2022

Improving the existing designs of screw conveyors can significantly increase productivity and expand the functionality of transport mechanisms, which leads to further development of production. One of the reserves to increase the functionality of screw transport mechanisms is to improve the transportation process by developing combined screw working bodies that will ensure the simultaneous movement and grinding of materials. The objestive of the work is to refine the mathematical model of productivity of the improved screw conveyor basing on coordination of supply of root crops from the loading channel to the auger and complex geometrical factor of filling the working space of a trench. The developed refined mathematical model allows to determine at the highest level the real productivity of simultaneous transportation and grinding of root crops on a separate technological unit, which is installed, for example, in the line of preparation and processing of root crops for biofuels. This allows to optimize the parameters and modes of operation of the entire processing complex at a practical level and ensure its estimated productivity of the manufacturing process.

Optimization of the parameters of working bodies root pile cleaner

Pankiv,

Pankiv

2024

Root crops are valuable technical crops, and their raw material processing ensures the production of food (sugar, alcohol, juicy fodder for livestock, inulin for the field of medicine) and technical (renewable energy sources – biofuel) products is one of the types of organic fertilizers. The use of modern self-propelled bunker root harvesters in Ukraine, which are built according to the block-module principle, is profitable under the condition of seasonal production on a minimum area of 300 hectares or more. Therefore, in the conditions of management of multi-branch agricultural enterprises that grow root crops on small areas, an urgent technical and economic problem is the payback of technically complex and too expensive (from UAH 350 to 750 thousand per unit) root harvesting machines in connection with the specifics of the work – limited climatic terms of their use during the year (about one calendar month) and on small areas - up to 20...50 ha. Reducing the content of general soil and plant impurities in raw root crops by 0.5...1.5% reduces the total costs of their processing by an average of 10 to 15%, and reducing sticky soil by 0.5...0.8% reduces the costs of its separation (washing, scraping, etc.) on average from 8 to 12%. At the same time, the yield of the final processing product of higher quality is significantly increased by an average of 10...20%. The maximum permissible values of the work quality indicator in accordance with agrotechnical requirements were obtained with the following compromise values of the input factors: fodder and sugar beets: for augers of round section: rotation frequency of augers 150...160 rpm; rotation frequency of elastic elements 500...700 rpm; soil moisture 20...22%; speed of movement of the root harvesting machine up to 5...6 km/h; for elliptical screws: screw rotation frequency 120...160 rpm; rotation frequency of elastic elements 500...700 rpm; soil moisture 20...22%; speed of movement of the root harvesting machine up to 6...7 km/h; root crops of chicory: rotation frequency of the screw conveyor 140...150 rpm; soil moisture 20...22%; speed of movement of the root harvesting machine up to 6...7 km/h. The obtained results are a further step in the improvement of the methodology, methods of development and optimization of parameters of the work processes of transport and technological systems of root harvesting machines.