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Earthquake Versus Electric Field

(A Resistant Design with Piezo Ceramic Materials)

Ankur Tayal

Abstract This paper relates to vibration control using piezo electric materials. The vibration control efficiency relies on the optimization of the vibration energy transfer between a structure and Lead-Zirconate-Titanate (PZT) piezoelectric ceramic material. In this paper, an analytical study of electric field produced by applied stresses of earthquake vibrations to control and damp them is presented .The influence of electric field formed around ceramic material forms a shield to further counter effect the upcoming vibrations i s discussed.

Index Terms Coupling Electric field , Piezo Lead-Zirconate-titanate (PZT), Shield, Strain, Stress, Voltage

1. INTRODUCTION

Earthquake resistant design structures has been a
subject of engineering research for the past few
decades till now. Many Researches in this field
have undergone to control the vibratory effect of earthquakes. Earthquakes occur due to sudden release of stored energy . Most earthquakes take place along faults in the upper 25 miles of the earth's surface when one side rapidly moves relative to the otherside of the fault. This sudden motion causes shock waves (seismic waves) to radiate from their point of origin called the focus and travel through the earth. The stresses developed due to these vibrations are firstly affect the foundation of a structure. Hagood and von Flotow (1991) have demonstrated vibrations of a structure can be controlled with piezo materials . The piezoelectric materials convert vibration energy to electrical energy by polarizing themselves. Due to polarization voltage is induced which can be used to create a 3d network or cover of electrical fields around . The cover of field formed act as a shield between the foundation and earthquake vibrations.

2. WORKING OF PIEZO MATERIALS

2.1 Direct Piezoelectric Effect

Deformation of the piezo material causes an electrical charge on certain opposite faces of the piezo electric material. The separation between negative and positive charge sites (the electric dipole) leads to a net polarization. The polarization generates a
voltage. The produced voltage can be used to create
electric field lines. These field lines generated
are in form of concentric circles around the crystal. Figure 1. shows a schematic diagram of piezo material
with applied force . The force leads to polarization of the
crystal with positive side on upper side and negative down side.

Figure 1. Generation of Voltage

This generates a high power voltage. Due to high power voltage current is set up as shown. This set up current has tendency to create Shield of electric field around them.

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The research paper published by IJSER journal is about Earthquake versus Electric Field - A Resistant Design with Piezo Ceramic Materials 2

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a)

When a poled

ceramic material is

maintained below

its curie temperature and is


Figure 2. A plot for voltage produced current and electric field in Piezo material

2.2 Electric Field As Shield

The key concept of this paper lies in the fact that laying of such materials within the foundations of structures such that in conditions of earthquakes these material experiences the net effective stress resulting in effective strain which Creates electric field pattern This pattern acts as protecting shield or umbrella for the upcoming vibrations. The shield will continue until the effect of vibrations last longs and keep on acting against the vibrations of earthquakes by strong opposite head on collisions against them.

2.3 Actuation Of Structural Components By

Piezoelectric Crystals

subjected to a macroscopic expansion along the
poling axis and contraction perpendicular to
it dipoles respond collectively to produce an effective electric field.
b) Electric field due to geometry and deformation of PZT poled in the 3 direction of a simple cube.

Figure 3. Electric field lines around cubic
Crystal

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Figure 4. Electric Field Patterns forming Field line Shield

3. BASIC KEY CONCEPT MODEL

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Figure 5. Research Concept Model
Figure 5 illustrates the basic concept of the research work. The model represents the structure installed with a piezo ceramic material . This material when acted upon by earthquake vibrations generates strong yellow colour electric field around the foundation of structure. Collision between electric field and earthquake vibrations occurs which results in resisting and damping of destructive vibrations and safeguarding the structure from hazardous earthquake.

4. ELECTRIC FIELD AND STRAIN RELATIONSHIP

4.1 “g" Constant:

The piezoelectric constants relating the electric field produced by a mechanical stress are termed the voltage constants, or the "g" coefficients. The units may then be
expressed as volts/meter per newtons/square meter.

Output electric field is obtained by dividing the calculated voltage by the thickness of ceramic between electrodes . A

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"33" subscript indicates that the electric field and the
mechanical stress are both along the polarization axis . A "31" subscript signifies that the pressure is applied at right angles to the polarization axis, but the voltage appears on the same electrodes as in the "33" case. A "15" subscript implies that the applied stress is shear and that the resulting electric field is perpendicular to the polarization axis. High gij constants favor large voltage output. Although the g coefficient are called voltage coefficients, it is also correct to say the gij is the ratio of strain developed over the applied charge density with units of meters per meter over coulombs per square meter.

4.2 “dij” Constant

Strain refers to effective deformation produced due
to application of stresses. Relationship between field strength and strain is quantified by the piezoelectric moduli dij.
Where

i : direction of the electric field

j : direction of the resulting normal strain

For example:

Where

V : voltage applied in the 3-direction

t : thickness of the specimen

Typical values of the piezoelectric of piezoelectric moduli are given in following table:

For the same produced strain due toequal applied stresses, soft
PZT will generate strong electric shield.

5. MATHEMATICAL SOLUTIONS WITH MODEL REFERENCES FOR GENERATED VOLTAGE AND FIELD

5.1 Electrical Equivalent Circuit

The study of the transient dynamic characteristics of a PZT bender utilizing electrical equivalent models has been performed in previous studies and the model has shown fair accuracy in various conditions of mechanical stress The electrical equivalent model has been studied and implemented in this research compare the accuracy and validity of the and the analytical results from models based on beam theory and energy conservation for PZT beam.

Figure 6. An electric equivalent circuit model for a PZT
beam
where a voltage source is connected in series with an inductor, a resistor and a capacitor that build a resonant circuit. The transformer represents the voltage adaptation while the capacitor indicates the inherent capacitance of the device.
The circuit can be described by using Kirchhoff’s voltage
law:

The equivalent circuits leads to the correlation between the strain e and voltage V .

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5.2 Beam Theory (Timoshenko and Euler–Bernoulli)

The static analysis of a piezoelectric cantilever sensor is

typically performed by the use of calculations employed for de ection of a thermal bimorph proposed by Timoshenko The principle is based on the strain compatibility between three heterogeneous bimorph where two piezoelectric layers are bonded on cantilever beams joined along the along the bending axis . Due to forces applied by one or all of the layers, the de ection of the three layer structure is derived from a static equilibrium state. The structure considered is a piezoelectric is assumed to be approximately the same to those of the structure, simply because of the assumption both sides of a purely elastic layer, i.e. brass with a pure elasticity is sandwiched between the upper and lower layers of the PZT material. The beam thickness is much less than the piezoelectric – induced curvature. The radius of curvature for all the layers that the thickness is much less than the overall beam curvature. The total strain at the surface of each layer is the sum of the strains caused by the piezoelectric effect the axial force, and the bending.

where εpiezo in the linear constitutive equation above considers the transverse piezoelectric coupling coefficient d31 and the electric field across the thickness of the layer Ei· for a piezoelectric material, t1 and t3 are the thickness of the PZT layer and t2 is the thickness of the center shim, Ai is the area of the corresponding layer and Yi is the young’s modulus of elasticity.
Hence the radius of curvature is given by the term:

Figure7. Geometry of strain beam due to Stresses

Euler–Bernoulli beam theory describes the relationship between the radius of curvature and the force applied, by the following equation:

where ρ is the density, I is the moment of inertia and F(t) is the applied force. A general solution for this equation is given by

Equations For Vibrations Produced Due to Displacement :

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The total energy of the beam is given as [15]:

the electric field is given by E = V/(2t3).

ωn, is the natural frequency obtained by solving the


transcendental equation:
The radius of curvature is given by the following equations:

Hence by substituting the radius of curvature term in equation (6), the voltage produced for the PZT is given by:

5.3 Conservation Of Energy

The principle is based on the fact that the total energy of the PZT bender stored is equal to the sum of the mechanical energy applied to the beam. When a mechanical stress is applied, the energy stored in a PZT layer is the sum of the mechanical energy and the electric-field-induced energy. Thus, the energy stored in a PZT layer is expressed as follows:

where σ is the stress and s is the stiffness matrix. The energy in the metal layer can be expressed by a simple equation

The total electrical energy is equal to a product of the charge and the voltage. Thus, the charge generated in the beam is obtained by a partial derivative of the total energy with respect to the voltage:

The capacitance of the piezoelectric material is described as the relation between the voltage and charge on the piezoelectric material.
where K31 is the coupling coefficient
Thus, the voltage generated is found as a function of the

applied force:
All of the models described above are solved by using Matlab/Simulink. Simulation results are compared with the experimental results in the following sections:

6. V AND E RELATIONSHIP

The scalar electric potential (voltage) is that the electric

field can be calculated from it. The component of

electric field in any direction is the negative of rate of
change of the potential in that direction. If the differential voltage change is calculated along a direction

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ds, then it is seen to be equal to the electric field component in that direction times the distance ds.


where:
k, l - natural numbers,
c, d - real numbers,
H - any positive real number.

The electric field can then be expressed as

For rectangular coordinates, the components of the electric field are



Thus taking the partial derivative of above all
Voltage equations Eq. [3] , [13] and [19] with x, y and z gives the electric field in that direction.

7. RESULTS

The above Electric field lines obtained when encounters
with the vibrations originating from focus of the earth , the collision between the two results in the slowly reducing and then simultaneously damping of the earthquake radiations. As they approaches close to crystal their effect reduces rapidly due to the continuous increase in intensity of electric field. Characteristic functions of earthquake
vibrations represented as functions in the form of their

mobility (1) or slowness (2):

where:
c - elastic elements,
m - inertial elements.
Thus V(s) and U(s) are the slowness functions which represents the slowing and damping down the effect of consecutive vibrations of earthquake. These factors results in losing of velocity of earthquake vibrations and gradually damping of them.

8. CONCLUSIONS

This paper presents a theoretical approach in the field of
civil engineering. The concept discussed above with mathematical solutions shows that using the ability of peizo ceramic materials to gets polarized under effective stresses resulting strain creates a potential

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difference within the crystal. This potential can be harnessed to produce high voltages. The partial derivative
of this voltage developed in three dimensions creates a network of electric field around the structure under which it is laid. This network acts a shield or cover to safeguard the structure from the consecutive effect of vibrations originating from focus of the earthquake. The voltage equations Provided in section [5.1],[5.2]and [5.3] shows voltage can be effectively produced in piezo materials whereas article [6] presents the solution to generate electric field from that voltage produced.
The slowness factor discussed under results in section [7] indicates the slowing and damping effect of vibrations under the influence of developed electric shield.

Acknowledgments

I would like to express my great gratitude and thanks to
1. Mrs. Archanaa Dongre
(Associate Professor, IPEC Ghaziabad)
2. Mrs. Anju Aggarwal
(Assistant professor, IPEC Ghaziabad)
For their most support and encouragement. They kindly read my paper and offered invaluable detailed advices on grammar, organization, and the theme of the paper.
I sincerely thank to my parents, family, and friends for their constantly inspiring and supporting nature.

Refrences

[1] N. W. Hagood and A. von Flotow, "Damping of Structural Vibrations with Piezoelectric Materials and Passive Electrical Networks", Journal of Sound and Vibration, 146(2), pp. 243 – 268, 1991

[2] ME 493 Introduction to Smart Structures and Materials,
SPRING 2011, METU, Ankara Dr. Gökhan O. ÖZGEN [3] Application of mechanical andelectrical elements in
reduction of vibration K. Białas* Institute
of Engineering Processes Automation and Integrated
Manufacturing Systems, Silesian University of
Technology, .ul. Konarskiego 18a, 44-100 Gliwice, Poland
[4] A Survey of Recent Innovations in Vibration Damping and Control Using Shunted Piezoelectric Transducers
S. O. Reza Moheimani, Senior Member, IEEE
[5] Modeling and analysis of a bimorph piezoelectric
cantilever beam for voltage generation J Ajitsaria1, S Y Choe1, D Shen2 and D J Kim2 , AL 36849 USA

AUTHOR

First Author : Ankur Tayal
B.tech (3rd year)
Department of Civil Engineering
Inderprastha Engineering Colleg
63 Site IV Surya Nagar Flyover
Road Sahibabd Ghaziabad U.P. ankurtayal3@gmail.com
Correspondence Author: Ankur Tayal
4647/15 Jai Mata Market Tri
Nagar New Delhi New Delhi –
110035
9582974527 (m)
011 – 27392941 ®
ankurtayal3@gmail.com

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