Conceptual directions for the development of driverless agricultural mobile power units

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Abstract

BACKGROUND: Currently, major global developers and manufacturers in the field of mobile agricultural machinery are working on the development of agricultural robotic systems. Particular attention is paid to the development of universal driverless mobile power units (MPU) capable of performing various technological operations autonomously, without human intervention. In the future, this makes it possible to exclude the operator from the MPU control process and to reconsider approaches to the issue of increasing the efficiency of technological operations. The existing trend of productivity improvement by increasing the main parameters of the unit, such as operating width, operating velocities, load capacity, etc., may change to an alternative path consisting in the use of numerous autonomous small-sized units comparable in performance (a swarm of agricultural robots). Thus, the use of driverless control systems makes it possible to use conceptually new approaches to the development of agricultural MPUs. In this regard, it becomes relevant to conduct the study aimed at identifying promising conceptual directions for the development of driverless MPUs and evaluating the efficiency of their application.

AIM: Identification of conceptual directions for the development of driverless driverless MPUs and a theoretical assessment of the efficiency of their application.

METHODS: The study object was the MPU transformation in the context of the development of driverless control systems. The study was based on scientific publications on the development of robotic agricultural tools, informational data of manufacturers of agricultural tractors and control systems for agricultural machinery. In the course of the study, such methods as information analysis, synthesis, methods of performance analysis of agricultural units and analysis of present cost of performing technological operations, adapted for driverless MPUs by the VIM, were used.

RESULTS: The prospects for the introduction of driverless MPUs, the existing digital and intelligent control systems of MPUs and the main factors hindering their development are analyzed. A classification of agricultural MPUs according to automation levels is proposed. The main directions of development are identified and conceptual models of driverless MPUs are proposed: universal driverless MPUs (driverless tractors) with keeping the existing traction class and power classification, universal (multifunctional) low-power driverless MPUs of the only traction class, separate power modules capable of being combined into a single driverless unit based on the coupled agricultural machine. The method is proposed and the equivalent number of driverless MPUs of each conceptual model for each traction class is calculated. An assessment of the impact of the use of the proposed conceptual models of driverless MPUs on the arable unit performance and the present cost of arable operations has been carried out.

CONCLUSIONS: Conceptual models for the advancing of driverless MPUs have been developed and comparative calculations of the efficiency of their application as part of arable units, helping to assess the possible prospects for their use, have been made.

About the authors

Ivan A. Starostin

Federal Scientific Agroengineering Center VIM

Author for correspondence.
Email: starwan@yandex.ru
ORCID iD: 0000-0002-8890-1107
SPIN-code: 7301-6845

Cand. Sci. (Engineering), Head of the Laboratory for Forecasting the Development of Machine Systems and Technologies in the Agro-Industrial Complex

Russian Federation, 5 1st Institutsky proezd street, 109428 Moscow

Aleksandr V. Eshchin

Federal Scientific Agroengineering Center VIM

Email: eschin-vim@yandex.ru
ORCID iD: 0000-0002-9368-7758
SPIN-code: 7610-5793

Cand. Sci. (Engineering), Senior Researcher at the Laboratory for Forecasting the Development of Machine Systems and Technologies in the Agro-Industrial Complex

Russian Federation, 5 1st Institutsky proezd street, 109428 Moscow

Teimur Z. Godzhaev

Federal Scientific Agroengineering Center VIM

Email: tgodzhaev95@yandex.ru
ORCID iD: 0000-0002-4496-0711
SPIN-code: 4808-7437

Head of the Modeling and Optimization of Mobile Energy Equipment Sector

Russian Federation, 5 1st Institutsky proezd street, 109428 Moscow

Svetlana A. Davydova

Federal Scientific Agroengineering Center VIM

Email: davidova-sa@mail.ru
ORCID iD: 0000-0002-1219-3335
SPIN-code: 1050-6034

Cand. Sci. (Engineering), Leading Researcher at the Laboratory for Forecasting the Development of Machine Systems and Technologies in the Agro-Industrial Complex

Russian Federation, 5 1st Institutsky proezd street, 109428 Moscow

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Supplementary files

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2. Fig. 3. Coupling of driverless MPUs with ploughs, unstriped and inter-row cultivators. a — conceptual model A; b — conceptual model B; c — conceptual model of C.

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3. Fig. 1. Advancing of autonomous control systems of agricultural MPUs.

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4. Fig. 2. Conceptual directions of development of driverless agricultural MPUs.

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5. Fig. 4. Results of calculation of equivalent number of driverless MPUs of the conceptual models A, B and C depending on drawbar category of a basic tractor.

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6.  Fig. 5. Assessed hour performance of arable units including driverless MPUs of various conceptual models.

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7. Fig. 6. Decreasing the present value of ploughing per hectare using driverless MPUs in comparison with basic tractors.

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