Évf. 7 szám 1 (2020)

Articles

Sway Control of 3-Cars Crane System Using Proposed Fuzzy-PID Controller

Megjelent:

2020-12-31

https://doi.org/10.17667/riim.2020.1/4.

Szerzők

Yildirim Şahin,

Erciyes University, Engineering Faculty, Mechatronics Engineering Kayseri, Turkey

Gordebil Aysegul

Erciyes University, Institute of Science, Mechatronics Engineering Kayseri, Turkey

Megtekintés

PDF (Angol)

Kulcsszavak

3 cars crane system control sway Fuzz controller PID controller

Licenc

Copyright (c) 2020 by the authors

This work is licensed under a Creative Commons Attribution 4.0 International License.

Hogyan hivatkozzuk

Kiválasztott formátum: APA

Yildirim, Şahin, & Gordebil, A. (2020). Sway Control of 3-Cars Crane System Using Proposed Fuzzy-PID Controller. Recent Innovations in Mechatronics, 7(1), 1-8. https://doi.org/10.17667/riim.2020.1/4. (Original work published 2024)

Hivatkozási formátumok

Hivatkozások
• ACM
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Beküldött 2020-02-28
Elfogadott 2020-10-12
Publikált 2020-12-31

Absztrakt

This paper presents a novel control approach for 3 cars crane systems. Nowadays; some problems for carrying unpredicted loads of crane systems exist. On the other hand; long bar loads are very important to carry without touch on other materials in factories. In this simulation study, fuzzy based controllers were designed to control vibrations of 3 cars crane system. The simulation results are improved and show this kind of controllers will be employed in real time such systems.

Hivatkozások

1. Ramli, L., Mohamed, Z., Abdullahi, A., M., Jaafar, H., I., Lazim, I., M., 2017, Control strategies for crane systems: A comprehensive review, Mechanical Systems and Signal Processing, 95: 1-23
2. Sorensen, K., Singhose, W. Dickerson, S., 2005, A controller enabling precise positioning and sway reduction in cranes with on-off actuation, 16th Triennial World Congress, Prague, Czech Republic, Elsevier IFAC Publications, 38(1): 580-585
3. Miranda-Colorado, R., Aguilar, L., T., 2019, A family of anti-swing motion controllers for 2D-cranes with load hoisting/lowering, Mechanical Systems and Signal Processing, 133: 106253
4. Lobe, A., Ettl, A., Steinboeck, A., Kugi, A., 2018, Flatness-based nonlinear control of a three-dimensional gantry crane, IFAC PapersOnLine, 22(51): 331-336
5. Giacomelli, M., Padula, F., Simoni, L., Visioli, A., 2018, Mechatronics, 56: 37-47
6. Mori, Y., Tagawa, Y., 2018, Vibration controller for overhead cranes considering limited horizontal acceleration, Control Engineering Practice, 81: 256-263
7. Lu, B., Fang, Y., Sun, N., 2018, Modeling and nonlinear coordination control for an underactuated dual overhead crane system, Automatica, 91: 244-255
8. Zhao, X., Huang, J., 2019, Distributed-mass payload dynamics and control of dual cranes undergoing planar motions, Mechanical Systems and Signal Processing, 126: 636-648
9. Smoczek, J., 2014, Fuzzy crane control with sensorless payload deflection feedback for vibration reduction, Mechanical Systems and Signal Processing, 46(1): 70-81
10. Ouyang, H., Xu, X., Zhang, G., 2020, Energy-shaping-based nonlinear controller design for rotary cranes with double-pendulum effect considering actuator saturation, Automation in Construction, 111: 103054
11. Shengzeng, Z., Xiongxiong, H., Haiyue, Z., Qiang, C., Yuanjing, F., 2020, Partially saturated coupled-dissipation control for underactuated overhead cranes, Mechanical Systems and Signal Processing, 136: 106449
12. Smoczek, J., Szpytko, J., 2014, Evolutionary algorithm-based design of a fuzzy TBF predictive model and TSK fuzzy anti-sway crane control system, Engineering Applications of Artificial Intelligence, 28: 190-200
13. Maghsoudi, M., J., Ramli, L., Sudin, S., Mohamed, Z., Husain, A., R., Wahid, H., 2019, Improved unity magnitude input shaping scheme for sway control of an underactuated 3D overhead crane with hoisting, Mechanical Systems and Signal Processing, 123: 466-482
14. Alghanim, K., A., Alhazza, K., A., Masoud, Z., N., 2015, Discrete-time command profile for simultaneous travel and hoist maneuvers of overhead cranes, Journal of Sound and Vibration, 345: 47-57
15. Piriadarshani, D., Sujitha, S., S., 2018, The role of transfer function in the study of stability analysis of feedback control system with delay, International Journal of Applied Mathematics, 31(6): 727-737
16. Lobontiu, N., 2017. System Dynamics for Engineering Students: Concepts and Applications, Elsevier Science, 786
17. Baburajan, S., 2017. Pitch Control of Wind Turbine Through PID, Fuzzy and Adaptive Fuzzy-PID Controllers. Rochester Institute of Technology RIT Scholar Works, Master Thesis, Rochester, 62
18. Suganthi, L., Iniyan, S., Samuel, A., A., 2015. Applications of fuzzy logic in renewable energy systems – A review, Renewable and Sustainable Energy Reviews, 48: 585-607
19. Visek, E., Mazzrella, L., Motta, M., 2014. Performance analysis of a solar cooling system using self tuning fuzzy-PID control with TRNSYS. ISES Solar World Congress, 2013, Milano, Energy Procedia, 57: 2609 – 2618