№74-9

Educational design and modelling of electro-hydraulic control system machine tool motion

S. Alekseyenko1, V. Derbaba1, V. Ruban1, M. Alekseyenko1

1Dnipro University of Technology, Dnipro, Ukraine

Coll.res.pap.nat.min.univ. 2023, 74:111-123

https://doi.org/10.33271/crpnmu/74.111

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ABSTRACT

Purpose. To present the design and modeling technology of real electrohydraulic systems, for use in the educational process of a higher educational institution, and the prospects of the proposed approach in the training of technical specialists. As an example, the model of the motion control system of the hydraulic cylinder of the device for fixing parts on the working table of a milling machine, created on the basis of components of the Festo company, is considered.

The methods. The methodological basis of the work is a systematic approach, which consists in the use of modern FluidSim software - comprehensive software for creating, modeling and studying, including electro-hydraulic circuits and educational equipment of the Festo company, which allows students to acquire and develop practical skills and at the same time simulate a real working environment . Additional advantages of computer and physical modeling in the educational process are the interactive component, which facilitates the visualization of educational material and improves the process of problem solving.

Findings. Taking into account the pedagogical features inherent in the world trends in technical education, the application of a comprehensive approach using computer and physical modeling in the training of technical specialists in the design of electrohydraulic systems is justified in the educational process. The sequence and results of the students' work on one of the options for the implementation of the educational project – the control system for the motion of the hydraulic cylinder of the device for fixing parts on the work table of the milling machine – have been demonstrated. The result of the proposed approach is also an increase in students' motivation, the achievement of a higher level of practical knowledge and skills compared to the traditional model of education.

The originality. A modified algorithm for the formation of an extended model of mastering educational material from electro-hydraulic devices and systems with the use of modern software and equipment has been developed. Which allows students to acquire and develop practical skills and at the same time simulate a real working environment.

Practical implementation. The materials of the work can serve as a basis for using the proposed integrated approach, which will improve the process of learning and teaching electrohydraulics, ensuring a higher level of learning outcomes, especially in terms of acquiring practical knowledge and skills.

Keywords: modern technical education, electrohydraulic systems, hydraulic drive of machine tools, design and modeling, FluidSim, Festo.

References

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6. Orošnjak, M., Jocanović, M., & Karanović, V. (2017). Simulation and modeling of a hydraulic system in FluidSim. XVII International Scientific Conference on Industrial Systems, 17, 50–53.

7. Suwandi, A., Alamsyah, N. F., Zariatin, D. L., Sulaksono, B., & Prayogi, E. (2020). Simulated design of hydraulic systems for fishing deck machinery hydraulic type with FluidSIM® software. AIP Conference Proceedings2227, 020012.
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