Sage Journals: Discover world-class research

Abstract

Use of springs made of an alloy with shape memory (SMA) to shape the dynamic characteristics of a resonance vibration screen is proposed in this paper. These springs change spring constant as a result of temperature changes. Thus it is possible to change their resonance frequency in real time. In the paper a mathematical model of a controlled SMA spring was formulated and its parameters were identified. In the model both the effect of spring coefficient changes and damping changes depending upon alloy temperature and spring vibration frequency were taken into consideration. Experimental investigations of the examined spring and screen physical model were carried out and selected characteristics were also included. The investigations were carried out at the Dynamics and Control of Structures Laboratory of AGH University of Science and Technology. The control law was formulated. Simulation investigations of the mathematical vibration screen model in both open and closed loop systems were made. It was shown that the elaborated control system is robust of vibration mass changes by as much as ±30%.

Keywords

smart system vibration shape memory alloys vibrating screen smart suspension experimental data model identification

References

Krauze

Kotwica

, and Raczka

, “Laboratory and underground tests of cutting heads with disc cutters,” Archives of mining sciences, Vol. 54, No. 2, pp. 239–260, 2009.

Babitsky

V. I.

, “Autoresonant mechatronic systems,” Mechatronics, Vol. 5, No. 5, pp. 483–495, 1995.

Sokolov

I. J.

Babitsky

V. I.

, and Halliwell

N. A.

, “Autoresonant vibro-impact system with electromagnetic excitation,” Journal of Sound and Vibration, Vol. 308, No. 3–5, pp. 375–391, Dec. 2007.

Chen

and Tong

, “Application of the DEM to screening process: A 3D simulation,” Mining Science and Technology (China), Vol. 19, No. 4, pp. 493–497, Jul. 2009.

Dong

K. J.

and Yu

A. B.

, “Numerical simulation of the particle flow and sieving behaviour on sieve bend/low head screen combination,” Minerals Engineering, Vol. 31, pp. 2–9, May 2012.

Jablonski

and Ozga

, “Distribution of Stochastic Impulses Acting on an Oscillator as a Function of Its Motion,” Acta physica polonica A, Vol. 118, No. 1, pp. 74–77, 2010.

Wang

and Tong

, “Screening efficiency and screen length of a linear vibrating screen using DEM 3D simulation,” Mining Science and Technology (China), Vol. 21, No. 3, pp. 451–455, May 2011.

Yue-Min

Chu-Sheng

Xiao-Mei

Cheng-Yong

Yi-Bin

, and Ziting

, “Dynamic design theory and application of large vibrating screen,” Procedia Earth and Planetary Science, Vol. 1, No. 1, pp. 776–784, Sep. 2009.

Xiao

and Tong

, “Characteristics and efficiency of a new vibrating screen with a swing trace,” Particuology, Apr. 2013.

10.

Sokolov

I. J.

and Babitsky

V. I.

, “Phase Control of Self-Sustained Vibration,” Journal of Sound and Vibration, Vol. 248, No. 4, pp. 725–744, Dec. 2001.

11.

Otsuka

and Wayman

C.M.

, Shape Memory Materials. Cambridge, 1998.

12.

Raczka

Konieczny

, and Sibielak

, “Laboratory Tests of Shape Memory Alloy Wires,” Solid State Phenomena, Vol. 199, pp. 365–370, Mar. 2013.

13.

Kwasniewski

Piotrowska

Raczka

, and Sibielak

“The mathematical model of a hydrostatic transmission for controller design,”, in Proceedings of the IASTED International Conference on Modelling and Simulation, 2003, pp. 275–280.

14.

Raczka

Sibielak

, and Bah

“The stand for testing piezoelectric elements,”, in Proceedings of the 15th International DAAAM Symposium: Intellignet Manufacturing & Automation: Globalisation – Technology – Men -Nature, 2004, pp. 389–390.

15.

Sibielak

, “Optimal controller for vibration isolation system with controlled hydraulic damper by piezoelectric stack,” Mechanical Systems and Signal Processing, Vol. 36, No. 1, pp. 118–126, Mar. 2013.

16.

Sibielak

Raczka

, and Konieczny

, “Modified Clipped-LQR Method for Semi-Active Vibration Reduction Systems with Hysteresis,” Solid State Phenomena, Vol. 177, pp. 10–22, Jul. 2011.

17.

Flaga

Kata

, and Sapihski

“MICROSTRUCTURE EVALUATION OF Ni-Mn-Ga ALLOY,”, pp. 6–10, 2010.

18.

Raczka

Konieczny

, and Sibielak

, “Mathematical Model of a Shape Memory Alloy Spring Intended for Vibration Reduction Systems,” Solid State Phenomena, vol. 177, pp. 65–75, Jul. 2011.

19.

Sawitoński

Mçżyk

, and Klein

“Application of smart materials in vibration control systems,”, Vol. 24, No. 1, pp. 291–296, 2007.

20.

Raczka

, “Controlled SMA spring in Frahm's vibration absorber,” Mechanics, vol. 22, 2003.

21.

Williams

Chiu

, and Bernhard

, “Adaptive-Passive Absorbers Using Shape-Memory Alloys,” Journal of Sound and Vibration, Vol. 249, No. 5, pp. 835–848, Jan. 2002.

22.

Williams

K. A.

Chiu

G. T.-C.

, and Bernhard

R. J.

, “Dynamic modelling of a shape memory alloy adaptive tuned vibration absorber,” Journal of Sound and Vibration, Vol. 280, No. 1–2, pp. 211–234, Feb. 2005.

23.

Williams

K. A.

Chiu

G. T.-C.

, and Bernhard

R. J.

, “Nonlinear control of a shape memory alloy adaptive tuned vibration absorber,” Journal of Sound and Vibration, vol. 288, no. 4–5, pp. 1131–1155, Dec. 2005.

Application of an SMA Spring for Vibration Screen Control

Abstract

Keywords

References