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2022 | OriginalPaper | Buchkapitel

Model of the Pneumatic Positional Unit with a Discrete Method for Control Dynamic Characteristics

verfasst von : Mikhaylo Cherkashenko, Oleksandr Gusak, Aleksandr Fatyeyev, Nadezhda Fatieieva, Alexander Gasiyk

Erschienen in: Advances in Design, Simulation and Manufacturing V

Verlag: Springer International Publishing

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Abstract

At present, it appears that systems of pneumatic units with discrete and analog control, in which the required analog law of motion of the output member is provided with the help of discrete switchgear, offer a promising potential. When developing the schemes of positional hydraulic-pneumatic units, the parameters of the movement of the hydraulic-pneumatic unit are studied, namely: the value of displacement, speed, and acceleration of its output member. To carry out the simulation, a design based on discrete switchgear was taken as the basis for the pneumatic positional unit. Solving the inverse problem, i.e., with the law of motion of the output member of the pneumatic unit (specifying the positioning function) known, we determine the mandatory law of change in the effective areas of the control line and represent each equation of the dynamic model as block diagrams. A mathematical model of the system of pneumatic positional units with program control was developed. It considers the features of the system of pneumatic units and consists of mathematical models of the actuator, a real-time control line model, and a real-time control system. The proposed algorithm for analysis of dynamic characteristics using the MATLAB simulation environment confirms the adequacy of the mathematical models describing the operation of a positional pneumatic unit implemented on discrete pneumatic equipment. The developed algorithm is advisable to analyze the operation of the existing one and for designing new technological equipment.

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Sokol, Y., Cherkashenko, M.: Synthesis of control schemes of drives system. NTU “KhPI” Publ., Kharkiv (2018)

Zhou, Y., Li, Y.: PLC control system of pneumatic manipulator automatic assembly line based on cloud computing platform. J. Phys. Conf. Ser. 1744, 022011 (2021)

Chelabi, M.A., Basova, Y., Hamidou, M.K., Dobrotvorskiy, S.: Analysis of the three-dimensional accelerating flow in a mixed turbine rotor. J. Eng. Sci. 8(2), D1–D7 (2021). https://doi.org/10.21272/jes.2021.8(2).d2CrossRef

Filatov, D., Minav, T., Heikkine, J.: Adaptive control for direct-driven hydraulic drive. In: 11th International Fluid Power Conference, vol. 1, pp. 110–119. RWTH Aachen University, Aachen (2018)

Heikkilä, M., Linjama, M.: Fault-tolerant control of a multi-outlet digital hydraulic pump-motor. In: 11th International Fluid Power Conference, vol. 1, pp. 144–157. RWTH Aachen University, Aachen (2018)

Kanagasabai, L.: Real power loss reduction by enhanced RBS algorithm. J. Eng. Sci. 8(2), E1–E9 (2021). https://doi.org/10.21272/jes.2021.8(2).e1CrossRef

Zhao, S., Li, D., Zhou, J., Sha, E.: Numerical and experimental study of a flexible trailing edge driving by pneumatic muscle actuators. J. Actuators 10(7), 142 (2021)CrossRef

Cantoni, C., Gobbi, M., Mastinu, G., Meschini, A.: Brake and pneumatic wheel performance assessment – a new test rig. Measurement 150(6), 107042 (2019)

Hufnagl, H., Čebular, A., Stemler, M.: Trends in pneumatics – digitalization. In: International Conference “Fluid Power 2021”: Conference Proceedings, pp. 15–28. University Press, Maribor (2021)

10.

Zhang, Q., Kong, X., Yu, B., Ba, K., Jin, Z., Kang, Y.: Review and development trend of digital hydraulic technology. J. Appl. Sci. 10(2), 579 (2020)CrossRef

11.

Rager, D., Neumann, R., Post, P., Murrenhoff, H.: Pneumatische antriebe für industrie 4.0 – pneumatic drives for industry 4.0. In: Mechatronik (2017)

12.

Rager, D., Doll, M., Neumann, R., Berner, M.: New programmable valve terminal enables flexible and energy-efficient pneumatics for Industry 4.0. In: 11th International Fluid Power Conference, vol. 1, pp. 208–221. RWTH Aachen University, Aachen (2018)

13.

Siivonen, L., Paloniitty, M., Linjama, M., Sairiala, H., Esque, S.: Digital valve system for ITER remote handling – design and prototype testing. J. Fusion Eng. Des. 146, 1637–1641 (2019)CrossRef

14.

Pavlenko, I., et al.: Effect of superimposed vibrations on droplet oscillation modes in prilling process. Processes 8(5), 566 (2020). https://doi.org/10.3390/pr8050566CrossRef

15.

Lu, S., Chen, D., Hao, R., Luo, S., Wang, M.: Design, fabrication and characterization of soft sensors through EGaIn for soft pneumatic actuators. Measurement 164(11), 107996 (2020)CrossRef

16.

Belforte, G., Mauro, S., Mattiazzo, G.: A method for increasing the dynamic performance of pneumatic servosystems with digital valves. Mechatronics 14, 1105–1120 (2004)CrossRef

17.

Pavlenko, I., Ivanov, V., Gusak, O., Liaposhchenko, O., Sklabinskyi, V.: Parameter identification of technological equipment for ensuring the reliability of the vibration separation process. In: Knapcikova, L., Balog, M., Perakovic, D., Perisa, M. (eds.) 4th EAI International Conference on Management of Manufacturing Systems. EICC, pp. 261–272. Springer, Cham (2020). https://doi.org/10.1007/978-3-030-34272-2_24CrossRef

18.

Gao, Q., Linjama, M., Paloniitty, M., Zhu, Y.: Investigation on positioning control strategy and switching optimization of an equal coded digital valve system. Proc. Inst. Mech. Eng. Part I J. Syst. Control Eng. 234(8), 959–972 (2019)

19.

Ivanov, V., Pavlenko, I., Kuric, I., Kosov, M.: Mathematical modeling and numerical simulation of fixtures for fork-type parts manufacturing. In: Knapčíková, L., Balog, M. (eds.) Industry 4.0: Trends in Management of Intelligent Manufacturing Systems. EICC, pp. 133–142. Springer, Cham (2019). https://doi.org/10.1007/978-3-030-14011-3_12CrossRef

20.

Šitum, Ž., Benić, J., Pejić, K., Bača, M., Radić, I., Semren, D.: Design and control of mechatronic systems with pneumatic and hydraulic drive. In: International Conference “Fluid Power 2021”: Conference Proceedings, pp. 179–194. University Press, Maribor (2021)

21.

Šitum, Ž., Benić, J., Grbić, Š., Vlahović, F., Jelenić, D., Kosor, T.: Mechatronic systems with pneumatic drive. In: International Conference “Fluid Power 2017”: Conference Proceedings, pp. 281–293. University Press, Maribor (2017)

22.

Colombo, F., Mazza, L., Pepe, G., Raparelli, T., Trivella, A.: Inverted pendulum on a cart pneumatically actuated by means of digital valves. In: Aspragathos, N.A., Koustoumpardis, P.N., Moulianitis, V.C. (eds.) RAAD 2018. MMS, vol. 67, pp. 436–444. Springer, Cham (2018). https://doi.org/10.1007/978-3-030-00232-9_46CrossRef

23.

Elsaed, E., Abdelaziz, M., Mahmoud, N.: Investigation of a digital valve system efficiency for metering-in speed control using MATLAB/Simulink. In: International Conference on Hydraulics and Pneumatics HERVEX, 23rd edn., pp. 120–129 (2017)

Titel: Model of the Pneumatic Positional Unit with a Discrete Method for Control Dynamic Characteristics
verfasst von: Mikhaylo Cherkashenko
Oleksandr Gusak
Aleksandr Fatyeyev
Nadezhda Fatieieva
Alexander Gasiyk
Verlag: Springer International Publishing
Buch: Advances in Design, Simulation and Manufacturing V
Print ISBN: 978-3-031-06043-4

Electronic ISBN: 978-3-031-06044-1

Copyright-Jahr: 2022
DOI: https://doi.org/10.1007/978-3-031-06044-1_8

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