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Journal of Dynamic Systems, Measurement, and Control | Volume 132 | Issue 3 | Research Paper
Research Papers

Motion Control of a Container With Slosh: Constrained Sliding Mode Approach

[+] Author and Article Information
Hanz Richter

Department of Mechanical Engineering, Cleveland State University, 245 Stilwell Hall, 2121 Euclid Avenue, Cleveland, OH 44115h.richter@csuohio.edu

J. Dyn. Sys., Meas., Control 132(3), 031002 (Apr 14, 2010) (10 pages) doi:10.1115/1.4001329 History: Received April 06, 2008; Revised February 08, 2010; Published April 14, 2010; Online April 14, 2010
Article
References
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Citing Articles

A constrained sliding mode control methodology developed by the author is applied to the motion control of an open container filled with liquid. The objective is to control the position of the container to meet the performance and robustness requirements, and to specify a safe operating set, i.e., the set of initial conditions from which the system can be operated without exceeding a prescribed liquid level and additional constraints. A conventional sliding mode regulator is designed first to address nominal performance in the sliding mode. Then, a robustly invariant cylinder formed as the Cartesian product of an ellipsoid, and a closed interval is constructed using linear matrix inequalities. A set of constraint qualification conditions are evaluated to ensure that the intersection of the cylinder and the state constraints is robustly positively invariant, constituting the required operating set. Simulations and experimental results corresponding to a high-speed transfer validate the methodology.
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Copyright © 2010 by American Society of Mechanical Engineers
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References

1
Armenio, V., 1992, “Dynamic Behavior of Free Surface Liquids on Ships,” Ph.D. thesis, Department of Naval Architecture, University of Trieste, Trieste, Italy.
2
Peterson, L., Crawley, E. F., and Hansman, R., 1989, “Nonlinear Fluid Slosh Coupled to the Dynamics of a Spacecraft,” AIAA J., 27 (9), pp. 1230–1240.  [CrossRef]
3
Graham, E., and Rodriguez, A. M., 1952, “Characteristics of Fuel Motion Which Affect Airplane Dynamics,” J. Appl. Mech., 19 , pp. 381–388.
4
Popov, G., Sankar, S., Sankar, T. S., and Vatistas, G. H., 1993, “Dynamics of Liquid Sloshing in Horizontal Cylindrical Road Containers,” Proc. Inst. Mech. Eng., Part C: J. Mech. Eng. Sci., 207 (C6), pp. 399–406.  [CrossRef]
5
Grundelius, M., 2001, “Methods for Control of Liquid Slosh,” MS thesis, Lund Institute of Technology, Lund, Sweden.
6
Feddema, J., Dohrmann, C. R., Parker, G. G., Robinett, R. D., Romero, V. J., and Schmitt, D. J., 1997, “Control for Slosh-Free Motion of an Open Container,” IEEE Control Syst. Mag., 17 (1), pp. 29–36.  [CrossRef]
7
Grundelius, M., 2000, “Iterative Optimal Control of Liquid Slosh in an Industrial Packaging Machine,” Proceedings of the 39th IEEE Conference on Decision and Control , Nassau, Bahamas, pp. 3427–3432.
8
Blanchini, F., 1999, “Set Invariance in Control,” Automatica, 35 , pp. 1747–1767.  [CrossRef]
9
Nagumo, M., 1942, “Über die Lage der Integralkurven gewöhnlicher Differentialgleichungen,” Proc. Phys. Math. Soc. Jpn., 24 , pp. 272–559.
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O’Dell, B., and Misawa, E., 2002, “Semi-Ellipsoidal Controlled Invariant Sets for Constrained Linear Systems,” ASME J. Dyn. Syst., Meas., Control, 124 , pp. 98–103.  [CrossRef]
11
Innocenti, M., and Falorni, M., 1998, “State Constrained Sliding Mode Controllers,” Proceedings of the American Control Conference , pp. 104–108.
12
Keleher, P., and Stonier, R., 2002, “Adaptive Terminal Sliding Mode Control of a Rigid Manipulator With Uncertain Dynamics Incorporating State Constraints,” Aust. N. Z. Ind. Appl. Math. J., 43E , pp. E102–E152.
13
Richter, H., O’Dell, B., and Misawa, E., 2007, “Robust Positively Invariant Cylinders in Constrained Variable Structure Control,” IEEE Trans. Autom. Control, 52 (11), pp. 2058–2069.  [CrossRef]
14
Utkin, V., and Young, K., 1978, “Methods for Constructing Discontinuity Planes in Multidimensional Variable Structure Systems,” Autom. Remote Control (Engl. Transl.), 39 , pp. 1466–1470.
15
Edwards, C., and Spurgeon, S., 1990, "Sliding Mode Control", Prentice-Hall, Englewood Cliffs, NJ.
16
Itkis, U., 1977, "Control Systems of Variable Structure", Wiley, New York.
17
Slotine, J., and Li, W., 1990, "Applied Nonlinear Control", Prentice-Hall, Englewood Cliffs, NJ.
18
Utkin, V., 1992, "Sliding Modes in Control Optimization", Springer-Verlag, Berlin.
19
Richter, H., 2004, “Theoretical Tools and Software for Modeling, Simulation and Control Design of Rocket Test Facilities,” NASA Technical Report No. SSTI-8060-0001.
20
Brockman, M. L., and Corless, M., 1998, “Quadratic Boundedness of Nominally Linear Systems,” Int. J. Control, 71 (6), pp. 1105–1117.  [CrossRef]
21
Coulson, C., 1955, "Waves", Interscience Publishers, New York.
22
Su, T. C., Lou, J. K., Flipse, J. E., and Bridges, T. J., 1982, “A Numerical Analysis of Large Amplitude Liquid Sloshing in Baffled Containers,” Technical Report, U.S. Department of Transportation, Final Report No. MARD-940-82046.

Figures

Grahic Jump Location
+Generic plant structure for slosh problem
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Generic plant structure for slosh problem
Figure 1

Generic plant structure for slosh problem

Grahic Jump Location
+Tank and sensor mounted on the slide
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Tank and sensor mounted on the slide
Figure 2

Tank and sensor mounted on the slide

Grahic Jump Location
+Schematic of the measurement and control system
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Schematic of the measurement and control system
Figure 3

Schematic of the measurement and control system

Grahic Jump Location
+Model and experimental frequency response
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Model and experimental frequency response
Figure 4

Model and experimental frequency response

Grahic Jump Location
+Time-domain model prediction
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Time-domain model prediction
Figure 5

Time-domain model prediction

Grahic Jump Location
+Simulation results
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Simulation results
Figure 6

Simulation results

Grahic Jump Location
+Position-level plane
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Position-level plane
Figure 7

Position-level plane

Grahic Jump Location
+Velocity-level rate plane
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Velocity-level rate plane
Figure 8

Velocity-level rate plane

Grahic Jump Location
+Experimental results
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Experimental results
Figure 9

Experimental results

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