Effect of piezoelectric material on vibration of vessel of marine transportation
The drive arrangement of normal marine vessels involves a propeller coupled to a progression of shafts and diary orientation which is at last associated with a push bearing which sends the propeller pivotal power into the frame of the boat through a push block coupled to the mass head. For effortlessness, the framework is improved to a propeller, a solitary shaft, diary bearing and a push bearing. As the vessel travels through the sea, a wake is produced. This non-uniform wake field is the inflow to the propeller. The power produced by the propeller is additionally non-uniform. The impetus arrangement of a marine vessel is the principle supporter of commotion emanated from the vessel. It is along these lines important to diminish the commotion sent from the propeller into the sea and consequently the vibration that is created by the propeller that is thus communicated into the body. The inspiration for lessening commotion and vibration remembers diminishing mechanical wear for segments, expanding secrecy limit of military vessels, improving traveler and group solace, and decreasing the effect on marine conditions. The point of this theory is to dissect the shaky power created by the propeller, the power transmission ways, and techniques to quantify the power transmission through the push bearing continuously.
Keywords:piezoelectric ; ovibration ;vessel ; mechanical ; noise
 Kelley, C.R., et al., Optimizing Piezoelectric Material Location and Size for Multiple-Mode Vibration Reduction of Turbomachinery Blades. 2021. 143(2).
 Ding, D., Surface Characterization of Piezoelectric Sensor Materials for Potential Use in Reactor Vessel Sensors. 2019.
 Mohammadi, M., et al., Electro-elastic response of cylindrical sandwich pressure vessels with porous core and piezoelectric face-sheets. 2019. 225: p. 111119.
 Meskini, M., A.R.J.J.o.S.S. Ghasemi, and Materials, Electro-magnetic potential effects on free vibration of rotating circular cylindrical shells of functionally graded materials with laminated composite core and piezo electro-magnetic two face sheets. 2020: p. 1099636220909751.
 Pan, L., et al., Advances in piezo‐phototronic effect enhanced photocatalysis and photoelectrocatalysis. 2020. 10(15): p. 2000214.
 Mohammadi, M., M. Arefi, and S.A.J.J.o.P.V.T. Ahmadi, Two-dimensional electro-elastic analysis of FG-CNTRC cylindrical laminated pressure vessels with piezoelectric layers based on third-order shear deformation theory. 2020. 142(2).
 Rocha, R.T., et al., On the Positioning of a Piezoelectric Material in the Energy Harvesting From a Nonideally Excited Portal Frame. 2020. 15(12).
 Li, S., S. Liu, and L. Yang. Active Control of Vibration and Noise of Energy Equipment. in IOP Conference Series: Earth and Environmental Science. 2020. IOP Publishing.
 Sharma, P.J.M.T.P., Vibration analysis of FGPM beam: A review. 2021.
 Li, C., et al., Nonlocal vibrations and stabilities in parametric resonance of axially moving viscoelastic piezoelectric nanoplate subjected to thermo-electro-mechanical forces. 2017. 116: p. 153-169.
 Augustine, R., et al., Electrospun poly (vinylidene fluoride-trifluoroethylene)/zinc oxide nanocomposite tissue engineering scaffolds with enhanced cell adhesion and blood vessel formation. 2017. 10(10): p. 3358-3376.
 Mir, O., M. Shakouri, and M.J.S.A.S. Ashory, Gas pressure and density effects on vibration of cylindrical pressure vessels: analytical, numerical and experimental analysis. 2020. 2(1): p. 1-9.
 Deng, L., et al., A MEMS based piezoelectric vibration energy harvester for fault monitoring system. 2018. 24(9): p. 3637-3644.
 Bahaadini, R., M. Hosseini, and M.J.J.o.S.M. Paparisabet, Vibration Analysis of Vessels Conveying Blood Flow Embedded in Viscous Fluid. 2020. 12(4): p. 814-828.
 Li, J., et al., An Enhanced Hemostatic Ultrasonic Scalpel Based on the Longitudinal-Torsional Vibration Mode. 2021. 9: p. 10951-10961.
 Qian, W., et al., Piezoelectric material-polymer composite porous foam for efficient dye degradation via the piezo-catalytic effect. 2019. 11(31): p. 27862-27869
Copyright (c) 2021 Journal Port Science Research
This work is licensed under a Creative Commons Attribution-ShareAlike 4.0 International License.
- Published: 2021-11-11
- Issue: Vol. 4 No. 2 (2021): Transaction on Engineering, Technology and their Applications
- Section: Articles