Available online at www.sciencedirect.com ScienceDirect Procedia Engineering 144 (016 ) 668 673 1th International Conference on Vibration Problems, ICOVP 015 Effect of Heat on the Performance of Novel Energy Harvester by using PZT-5H Transducers K. Viswanath Allamraju a, *, K. Srikanth b a Research Scholar, NIT Warangal, 506004, India b Assistant Professor, NIT Warangal, 506004, India Abstract In this paper the effect of heat on the performance of novel energy harvester (NEH) by using PZT-5H circular transducers was mentioned. PZT-5H circular transducers were heated at three different temperatures such as 0 0 C, 60 0 C and 100 0 C and tested on 0g exciter under sinusoidal support excitation by using NEH. The observations were made on three parameters: temperature effect on impedance, temperature effect on resonant frequencies and temperature effect on the output voltage. At 0 0 C, the output voltage is 3 V and at 100 0 C the output voltage is 18 V is recorded. The observation is that the temperature effects the performance of PZT-5H circular transducers. 016 The The Authors. Published by Elsevier by Elsevier Ltd. This Ltd. is an open access article under the CC BY-NC-ND license (http://creativecommons.org/licenses/by-nc-nd/4.0/). Peer-review under responsibility of the organizing committee of ICOVP 015. Peer-review under responsibility of the organizing committee of ICOVP 015 Keywords: Novel energy harvester (NEH); circular transducers; heat; temperature effect. 1. Introduction In 1880, Curie brothers discovered the piezoelectricity. They used quartz material for their research. Piezoelectricity is the property of some materials to generate an electricity in response to applied mechanical load. Direct piezoelectric effect is the occurrence of generation of a voltage under mechanical stress. Converse piezoelectric effect is the occurrence of stress and strain when electric field is applied. * Corresponding author. Tel.: +91949060340. E-mail address: akvn87@gmail.com 1877-7058 016 The Authors. Published by Elsevier Ltd. This is an open access article under the CC BY-NC-ND license (http://creativecommons.org/licenses/by-nc-nd/4.0/). Peer-review under responsibility of the organizing committee of ICOVP 015 doi:10.1016/j.proeng.016.05.063
K. Viswanath Allamraju and K. Srikanth / Procedia Engineering 144 ( 016 ) 668 673 669 Nomenclature δ Mechanical strain σ Mechanical Stress Y Modulus of Elasticity d 33 Piezoelectric strain coefficient E Electric field D Electric Charge Displacement ε Dielectric constant of piezoelectric material m The proof mass c Damping coefficient k Spring stiffness ξ Damping factor ω Forced frequency The piezoelectric ceramics are highly brittle and they have better electromechanical properties when compared to the piezoelectric polymers. The upshot of annealing temperature on dielectric and ferroelectric properties of lead zirconate titanate(pzt-5h) thin films produced by oxide precursor method. Dielectric constant and dissipation factor were measured at 100 and film crystallized at 700 0 C for 1 hour in a paper [1].There are many researchers has studied the effect of temperature on structural level [, 3], thermal [4] and electrical properties [5]. In contrast to the studies on the dielectric, structural and electromechanical properties, there have been few reports on thermal behaviour in the PZT-5H systems. Not only knowledge of specific heat behaviour of the ferroelectric materials is important for both scientific and technological purposes, but also is more suitable for studying the phase transition behaviour than the structural properties test [6]. Because the specific heat (Cp) integrates over all possible temperature-dependent contributions to the free energy occurring on the time scale of the measurements. These contributions include the thermal evolution of the primary order parameter as well as contributions arising from coupling with other possible relaxations of the structure. The specific heat is also very sensitive to the presence of lattice defects that influence the phase transition but may not be clearly revealed in X-ray diffraction or dielectric permittivity measurements [7]. Heckman has elaborated the interaction between the stress, electric field and temperature with a simple diagram as shown in figure 1. In this paper authors applied the method of direct piezoelectric effect on the PZT-5H transducers after heating at different temperatures and studied the effect of temperature on the output voltage. Fig.1. Interaction between mechanical, thermal and electrical processes
670 K. Viswanath Allamraju and K. Srikanth / Procedia Engineering 144 ( 016 ) 668 673. Mathematical modelling of novel energy harvester(neh) PZT-5H 5H material having a density of 7.6 g/cm 3, Piezoelectric voltage constant of 4.8x10-3 m /c, relative dielectric constant of 1900, modulus of elasticity of 6.3x10 10 N/m, curie temperature is 30 0 C and Piezoelectric charge constant of 400x10-1 m/v [14]. We have used the 9 grams lead ball as a impact loader on the PZT-5H 5 H patches during excitation. Lead is having a properties of density is 11.3 g/cm 3, modulus of elasticity as 16 GPa and Poisson ratio as 0.44. The constitutive equations of PZT-5H 5H are as fallows [8]. δ = σ/y + d33e (1) D = ε E + d33σ () The displacement of lead mass related to the shaker is zt () The displacement of support is zt () xt () yt () (3) Then the differential equation of motion is mz() t cz() t kz() t my() t (4) n zt ( ) Ae t sin 1 nt Y sin t n 1 n n z Y n 1 n n (5) The total power dissipated in the damper under sinusoidal excitation was found to be given as [9] 3 Y m P( ) 1 n n n (6) Fig.. Equivalent mathematical model of NEH
K. Viswanath Allamraju and K. Srikanth / Procedia Engineering 144 ( 016 ) 668 673 671 3. Experimental procedure Figure 3b demonstrates the CAD model of NEH on 0g exciter. For designing NEH,two unimorph PZT-5H circular transducers having a diameter of 35 mm and 4 mm thickness, two supporting plates made of iron, size 5 x 5 x 0. cm and these two plates and PZT-5H circular transducers are supported by cylinder plastic pipe, length is 5 cm and diameter is 4 mm. A lead ball of 9 grams weight is used inside the cylinder to strike the PZT-5H transducers which have been heated already in oven at 0 0 C, 60 0 C and 100 0 C for one hour. The PZT-5H circular transducer is placed in a oven as shown in figure 3a. Fig. 3a. Heating of PZT-5H transducer inside the oven The heated PZT-5H transducers are used in the NEH and measured their performance by using 0g exciter at different frequencies and amplitudes. GW Instek digital storage oscilloscope has been used for measuring the output voltage. Sinusoidal excitation has been given to the support of the NEH via oscillator and amplifier. The arrangement of oscilloscope, amplifier, exciter and NEH have been shown in the figure 4. In the figure 4, the accelerometer connection to oscilloscope is not visible. Energy Harvester Novel Energy harvester Data Acquisition system Excite 0g Exciter Amplifier Oscilloscop Fig.3b. CAD model of NEH on 0g exciter Fig.4. Schematic diagram of experimental setup with NEH
67 K. Viswanath Allamraju and K. Srikanth / Procedia Engineering 144 ( 016 ) 668 673 4. Results and discussion After heating the PZT-5H circular transducers at 0 0 C, 60 0 C and 100 0 C at a period of 1 hour in an electric oven, which were tested on the 0 g exciter for observing the effect of temperature on the output voltage. The experiments were done and studied the effect of temperature on Impedance, resonant frequencies and finally the output voltage of PZT-5H transducers. Here the output voltage is AC. The experiments were performed to measure temperature effects on variation of impedance of the PZT-5H disc to determine the effect on resonant frequency. The measured impedance is graphically presented in figure 5 at different frequencies. When the temperature rises, the magnitude of the impedance decreases. Fig.5.Effect of Temperature on the electrical impedance of a PZT-5H disc Figure 6 describes the experimental data for the change in the natural frequency of the PZT-5H disc as a function of temperature. By observing the graphs at temperatures of 0 0 C, 60 0 C and 100 0 C, that the increase in temperature leads to decrease in resonant frequencies due to modulus of elasticity. Fig. 6. Change in frequency of the PZT-5H disc with temperature
K. Viswanath Allamraju and K. Srikanth / Procedia Engineering 144 ( 016 ) 668 673 673 It is observed from figure 7 that the increase in temperature decreases the output AC voltage from the NEH. The Vpeak-peak is maximum at 0 0 C and is minimum at 100 0 C. At 0 0 C, Vpeak-peak is 3 V and 18 V at 100 0 C. The constitutive equations explains that the V is proportional to d 33 and inversely proportional to ε. As temperature increases both d 33 and ε also increases, but the increase in ε is more prominent as compared to d 33 and hence the net effect is decrease in the output voltage. Fig.7. Effect of temperature on the output voltage 5. Conclusion The PZT-5H circular transducers were heated in the electric oven at 0 0 C, 60 0 C and 100 0 C for a period of one hour and tested on 0g exciter under sinusoidal excitation. The effect of temperature on impedance, resonant frequencies and output voltage were studied. The conclusion is at 0 0 C (V peak -peak is 3) the effect of temperature is less in comparison to 100 0 C (V peak -peak is 18) and thus temperature effects the performance of PZT-5H transducers. References [1] Araujo E.B, Eiras J.A, Effect of temperature and frequency on dielectric and ferroelectric properties of PZT-5H thin films, Material letters, 46,pp. 65,(000). [] Eremkin V.V, Smotrakov V.G and Fesenko E.G, Ferroelectrics 110, pp. 137-140,(1990). [3] Haun M.J, Furman E, Mc Kinstry H.A and Cross L.E.(1989).Ferroelectrics 99, pp. 7-35,(1989). [4] Rossetti G.A, Cahill P.F, Biederman R.R, and Sacco.A, Material letters 41, pp. 7,(1999). [5] Whatmore R.W, Clarke.R, and Glazer A.M, Journal of Physics C: Solid State Physics 11, pp. 3089-3095,(1997) [6] Rossetti G.A. and Maffei.N,Journal of Physics: Condensed Matter 17, pp. 39-53,(005). [7] Rossetti G.A. and Navrotsky A, Journal of Solid State Chemistry 144, pp. 188, (1999). [8] K.Viswanath Allamraju and Srikanth Korla, Materials today: Proceedings,pp. 1799-1804,(015). [9] Alper Erturk, Daniel J.Inman, Piezoelectric energy harvesting. ISBN: 978-0-470-6854-8,(011).