Characterization and tracking control of a nonlinear electrohydraulic valve-cylinder system

Das, J. C.; Mishra, Surendra Kumar; Paswan, Ramashankar; Kumar, Aditya; Sujit, Kumar; Saha, Rana; Mookherjee, Saikat

doi:10.1177/0954408914554021

Cited by 10 publications

(8 citation statements)

References 23 publications

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“…Within a range ± e 0 of the voltage variation, called the valve deadband, the leakage flow within the PV does not induce any perceptible piston motion. A previous study 29 on a similar system revealed the deadband as ±1.5 V. Beyond the deadband, the valve flow variation with the command voltage e was found as nonlinear, as highlighted in Figure 2(a). The figure additionally shows the associated pressure drop characteristics, where Δ P i ( i = 1 − 4 ) is the pressure drop across the proportional valve ports.…”

Section: Descriptions Of System and Controller Architecturementioning

confidence: 60%

“…Figure 2 represents the system nonlinearities characterized earlier. 29 The flow and pressure drop of the proportional valve were determined experimentally, as shown in Figure 2(a) with Q r being the flow measured in the return line by a screw flow meter. Within a range ± e 0 of the voltage variation, called the valve deadband, the leakage flow within the PV does not induce any perceptible piston motion.…”

Section: Descriptions Of System and Controller Architecturementioning

confidence: 99%

“…Figure 2(c) shows the friction characteristics where the static frictions were found 29 to be as high as F 0 − = − 814 N and F 0 + = 911 N . Compared to it, the cylinder used in another study with the same valve 22 had these two frictions as only ±33 N. 29 The figure also shows a significant hysteresis effect between the accelerating phase showing slip event S2 for small velocity zone and the decelerating phase showing stick zone as S1. Within these zones, the friction characteristics are also very uncertain.…”

Section: Descriptions Of System and Controller Architecturementioning

confidence: 99%

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Designing an optimized model-free controller for improved motion tracking by rugged electrohydraulic system

Mandal

Sarkar

Saha

et al. 2016

Proceedings of the Institution of Mechanical Engineers, Part I:

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Electrohydraulic actuation systems with proportional valves and industry-grade cylinders have widespread use due to their low cost and ease of maintenance. Achieving good tracking of output position of the piston in such a system by a proper controller design is the objective of this study. Due to various parameter uncertainties and complex nonlinearities like piston friction, valve deadband and flow characteristics, the variation of oil property with working temperature and air entrapment volume, the implementation of a model-based control becomes quite difficult for such systems. A notable contribution of this work is to couple a model-free fuzzy controller with a feedforward controller with all the parameters estimated by a real-coded genetic algorithm. Also, the optimizer has been used for identifying an appropriate fuzzy structure that is easy to implement in real time. A comprehensive experimental study has revealed the best fuzzy structure to be achieved through a Gaussian fuzzification of linear combination of the position and velocity errors as the input and singleton membership function for the output voltage actuating the proportional valve. Excellent responses with good disturbance rejection capability and energy efficiency have been achieved. These responses have emerged superior to those achieved in a similar system with different controller structures and in systems with much costlier components.

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Section: Descriptions Of System and Controller Architecturementioning

confidence: 60%

Section: Descriptions Of System and Controller Architecturementioning

confidence: 99%

Section: Descriptions Of System and Controller Architecturementioning

confidence: 99%

See 1 more Smart Citation

Designing an optimized model-free controller for improved motion tracking by rugged electrohydraulic system

Mandal

Sarkar

Saha

et al. 2016

Proceedings of the Institution of Mechanical Engineers, Part I:

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“…This can be calculated by measuring the pressure at both ends of the valve ports and the displacement of the valve spool. Das et al [13] and Borghi et al [14] used the polynomial equation with the flow rate as an independent variable to fit the pressure drop at both ends of the valve port for different valve openings. Åman et al [15] also used the pressure difference at both ends of the valve port to fit the flow rate through the valve port on the basis of considering the influence of the flow patterns.…”

Section: Indirect State Acquisition Technologiesmentioning

confidence: 99%

Research and Development of Electro-hydraulic Control Valves Oriented to Industry 4.0: A Review

Shen

Liu

et al. 2020

Chin. J. Mech. Eng.

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Electro-hydraulic control valves are key hydraulic components for industrial applications and aerospace, which controls electro-hydraulic motion. With the development of automation, digital technology, and communication technology, electro-hydraulic control valves are becoming more digital, integrated, and intelligent in order to meet the requirements of Industry 4.0. This paper reviews the state of the art development for electro-hydraulic control valves and their related technologies. This review paper considers three aspects of state acquisition through sensors or indirect acquisition technologies, control strategies along with digital controllers and novel valves, and online maintenance through data interaction and fault diagnosis. The main features and development trends of electro-hydraulic control valves oriented to Industry 4.0 are discussed.

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“…The prevalent design for position tracking purposes employs a proportional or servo directional control valve and a constant-pressure hydraulic source to control the position of the hydraulic actuator, similar to what is shown at the right-hand side of Figure 1. A rich body of research is available on improving the position tracking performance, through using control design methods such as robust control, 7,8 nonlinear control, 9,10 adaptive control, 11 sliding mode control, 12 and combinations of these techniques. 13 These efforts have been successful judging by the experimental results they provide.…”

Section: Introductionmentioning

confidence: 99%

Energy-efficient hydraulic actuator position tracking using hydraulic system operation modes

Saeedzadeh

Tivay

Zareinejad

et al. 2016

Proceedings of the Institution of Mechanical Engineers, Part E:

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Efficient actuation is an important requirement in electromechanical designs. Although hydraulic actuators are used extensively when high-magnitude forces are present in heavy machinery, they are not very energy-efficient. This paper aims to increase the efficiency of electro-hydraulic servo systems after introducing a controllable supply pressure and six mode of operation for different condition. This process allows for the system to have very low energy consumption whenever its environmental force agrees with its position reference signal. For this purpose, first, the electrohydraulic servo systems is modeled and a robust H 1 controller is designed for each mode of operation. The resulting control system works based on applying each mode strategy at right time to save energy. The effectiveness of this method is tested by conducting experiments on a hydraulic test rig and presenting the experimental results.

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Characterization and tracking control of a nonlinear electrohydraulic valve-cylinder system

Cited by 10 publications

References 23 publications

Designing an optimized model-free controller for improved motion tracking by rugged electrohydraulic system

Designing an optimized model-free controller for improved motion tracking by rugged electrohydraulic system

Research and Development of Electro-hydraulic Control Valves Oriented to Industry 4.0: A Review

Energy-efficient hydraulic actuator position tracking using hydraulic system operation modes

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