Quantitative Analysis of Damping Enhancement and Piezoelectric Effect Mechanism of CNTs/PMN/EP Composites

Pan, Shiyue; Li, Meijuan; Fei, Chen; Zhang, Huang; Shen, Qiang; Zhang, Lianmeng

doi:10.1155/2018/1253635

Advances in Materials Science and Engineering

2018

DOI: 10.1155/2018/1253635

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Quantitative Analysis of Damping Enhancement and Piezoelectric Effect Mechanism of CNTs/PMN/EP Composites

Shiyue Pan

Meijuan Li

Chen Fei

et al.

Abstract: New types of piezoelectric damping materials, including carbon nanotubes (CNTs)/lead magnesium niobate (PMN)/epoxy (EP) resin, are developed. The tan δarea (TA) analysis method is selected to evaluate the damping properties which obviously clarifies the effect of maximum loss factor (tan δ) and effective temperature range on damping properties. Furthermore, the dominant factor of damping enhancement is quantitatively analyzed via the value of TA. Compared with PMN, the interfacial friction of CNTs acts as the … Show more

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Cited by 3 publications

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“…Even though the enhancement of loss factor by the method in this work is not the largest, the flexibility and lightweight of composites play a prominent role in comparison. According to the details of Tian et al, 11 Pan et al, 31 and Hori et al, 32 the weight content of piezoelectric fillers are 60, 60, 90%, respectively, which are much larger than the content in this work (33.3%). Moreover, additional conductive fillers should be added to the matrix in those comparative reports, increasing the difficulty of synthesis and confusing the contributions of piezoelectric damping and the stick−slip effect by introducing conductive fillers.…”

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Interface Optimizing Core–Shell PZT@Carbon/Polyurethane Composites with Enhanced Passive Piezoelectric Vibration Damping Performance

Chen,

Lu,

Zheng

et al. 2024

ACS Appl. Mater. Interfaces

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Presently, piezoelectric materials are gradually playing a significant role within composites to improve the damping and vibrational attenuation capacities of host composites. Previous studies paid attention to isolating the mechanical damping contribution and piezoelectric contribution of polymer-based piezoelectric composites (PPCs). However, reports detailing the piezoelectric damping of such materials have not paid sufficient attention to the technologies and methods to improve the piezoelectric damping of PPCs. In this study, we propose novel damping polyurethane (PU)-based piezoelectric composites with carbon-coated piezoelectric fillers (PZT@C/PU) with improved piezoelectric damping ability. The mechanical damping and piezoelectric damping of composites were theoretically decoupled, and we elaborate on the mechanism enhancing piezoelectric damping through the carbon coating strategy by comparing with the composites with nonpiezoelectric fillers. The as-fabricated core–shell structure having an optimized interface exhibits the proposed PZT@C/PU composite pads with relatively prominent damping ability (loss factor tan δmax = 1.0, tan δRT = 0.3), ductility (400.63%), and sound isolating behavior (transmission loss TL > 23 dB). Moreover, the vibration test results of as-fabricated sandwich structural PZT@C/PU composite damping devices exhibit outstanding vibration attenuating behavior (damping ratio ζ = 0.198). The study herein validates that the carbon shell coated on piezoelectric fillers would effectively increase damping performance of PU-based piezoelectric composites by the enhancement of piezoelectric performance caused by carbon coating piezoelectric fillers, which indicates that this material has potential for future applications in the field of vibration and noise reduction, thereby driving forward and expanding the fundamental understanding in the area of PPCs damping and vibration attenuation.

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mentioning

confidence: 50%

Interface Optimizing Core–Shell PZT@Carbon/Polyurethane Composites with Enhanced Passive Piezoelectric Vibration Damping Performance

Chen,

Lu,

Zheng

et al. 2024

ACS Appl. Mater. Interfaces

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Damping performance analysis of carbon black/lead magnesium niobite/epoxy resin composites

et al. 2023

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Piezoelectric damping composites with excellent damping properties were prepared from carbon black (CB), lead magnesium niobate (PMN), epoxy resin, and polyether amine D-400. The tan δ {\rm{\tan }}\delta area (TA) analysis method is used to evaluate the leading factors of damping enhancement. This method clearly shows the influence of the maximum loss factor ( tan δ {\rm{\tan }}\delta max) and effective damping temperature range on damping performance, and the damping enhancement factors are quantitatively analyzed by TA values. When CB content is less than 8 wt%, viscoelastic damping and frictional energy dissipation are the main factors affecting polymer properties. When CB content reaches 8 wt%, the conductive network gradually forms, and the electric energy generated by PMN through the piezoelectric effect is dissipated by the conductive network, and the piezoelectric effect of PMN becomes the dominant factor. In this case, the maximum tan δ \tan \delta max and TA values of the composite are 1.93 and 27.58, respectively. The damping contribution of PMN and CB reaches 40.21% and 34.41%, respectively.

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Piezoresistive/piezoelectric intrinsic sensing properties of carbon nanotube cement-based smart composite and its electromechanical sensing mechanisms: A review

Teng

Luo

Gao

et al. 2021

Nanotechnology Reviews

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Structural health monitoring (SHM) technology based on the mechanical–electrical sensing effect of various intrinsic smart materials has a good application prospect. Carbon nanotube (CNT) has excellent electromechanical properties and hence can be doped into cement by appropriate dispersive means to produce CNT-modified cement-based smart material (CNTCS) with excellent electromechanical (piezoresistive/piezoelectric) capacity. CNTCS can be developed into a static/dynamic intrinsic sensor for SHM after effective packaging and calibration. Based on the characteristics of CNT, the dispersion methods and the dispersity characterization techniques of CNT in the water/cement matrix are summarized, and then the influence laws of various factors on piezoresistive and piezoelectric sensing behaviors of the corresponding CNTCS are also discussed. The full-frequency domain sensing mechanism of CNTCS is analyzed by combining its finite element model and electromechanical coupling theory, and the practicability of applying CNTCS as an SHM static/dynamic intrinsic sensor is further investigated.

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Quantitative Analysis of Damping Enhancement and Piezoelectric Effect Mechanism of CNTs/PMN/EP Composites

Cited by 3 publications

References 21 publications

Interface Optimizing Core–Shell PZT@Carbon/Polyurethane Composites with Enhanced Passive Piezoelectric Vibration Damping Performance

Interface Optimizing Core–Shell PZT@Carbon/Polyurethane Composites with Enhanced Passive Piezoelectric Vibration Damping Performance

Damping performance analysis of carbon black/lead magnesium niobite/epoxy resin composites

Piezoresistive/piezoelectric intrinsic sensing properties of carbon nanotube cement-based smart composite and its electromechanical sensing mechanisms: A review

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