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Sustainable yarn type-piezoelectric energy harvester as an eco-friendly, cost-effective battery-free breath sensor

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  • Maria Joseph Raj, Nirmal Prashanth
  • Alluri, Nagamalleswara Rao
  • Vivekananthan, Venkateswaran
  • Chandrasekhar, Arunkumar
  • Khandelwal, Gaurav
  • Kim, Sang-Jae

Abstract

A cost-effective layer-by-layer brush-coating technique was developed to fabricate a flexible yarn-based piezoelectric nanogenerator (FY-PNG) to harness abundant waste mechanical energy. A simple sol-gel method was used to synthesize the orthorhombic crystalline phase of bismuth titanate perovskite, i.e., Bi4Ti3O12 (BiTO). A single FY-PNG device generated a maximum peak-to-peak open-circuit voltage (VOC(P–P)), short-circuit current (ISC(P–P)), and instantaneous area power density of 60 V, 400 nA, and 18.5 mW/m2, respectively, upon application of a 1 N periodic mechanical load. The switching polarity of the FY-PNG demonstrated good phase shifting between the output signals and confirmed that the output derived from the device and not from any external sources. The working mechanism, electrical poling effect, force analysis, repeatability, stability, charging, energy storage analysis, and sensitivity to biomechanical force of the FY-PNG was thoroughly investigated. The FY-PNG device output was used to power five commercial green light-emitting diodes (LEDs) and a display system. Additionally, a non-invasive self-powered breathing sensor (SPBS) was developed to monitor human inhalation/exhalation. The repeatability and reproducibility of SPBS evaluated using different devices and test subjects demonstrated a good variation in output (i.e., 0.2–0.4 V) for inhalation/exhalation; the SPBS was also evaluated under slow/fast and constant breathing conditions. The proposed brush-coating technique for FY-PNGs is an efficient, cost-effective, eco-friendly, and easily scalable technique that can pave the way to the design of novel-shaped PNG devices for applications such as implantable self-powered biosensors and automotive electronic systems.

Suggested Citation

  • Maria Joseph Raj, Nirmal Prashanth & Alluri, Nagamalleswara Rao & Vivekananthan, Venkateswaran & Chandrasekhar, Arunkumar & Khandelwal, Gaurav & Kim, Sang-Jae, 2018. "Sustainable yarn type-piezoelectric energy harvester as an eco-friendly, cost-effective battery-free breath sensor," Applied Energy, Elsevier, vol. 228(C), pages 1767-1776.
    • Handle: RePEc:eee:appene:v:228:y:2018:i:c:p:1767-1776
    DOI: 10.1016/j.apenergy.2018.07.016
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    References listed on IDEAS

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    1. Sultana, Ayesha & Alam, Md. Mehebub & Middya, Tapas Ranjan & Mandal, Dipankar, 2018. "A pyroelectric generator as a self-powered temperature sensor for sustainable thermal energy harvesting from waste heat and human body heat," Applied Energy, Elsevier, vol. 221(C), pages 299-307.
    2. Johar, Muhammad Ali & Kang, Jin-Ho & Hassan, Mostafa Afifi & Ryu, Sang-Wan, 2018. "A scalable, flexible and transparent GaN based heterojunction piezoelectric nanogenerator for bending, air-flow and vibration energy harvesting," Applied Energy, Elsevier, vol. 222(C), pages 781-789.
    3. Trinh, V.L. & Chung, C.K., 2018. "Harvesting mechanical energy, storage, and lighting using a novel PDMS based triboelectric generator with inclined wall arrays and micro-topping structure," Applied Energy, Elsevier, vol. 213(C), pages 353-365.
    4. Ju, Suna & Ji, Chang-Hyeon, 2018. "Impact-based piezoelectric vibration energy harvester," Applied Energy, Elsevier, vol. 214(C), pages 139-151.
    5. Alluri, Nagamalleswara Rao & Selvarajan, Sophia & Chandrasekhar, Arunkumar & Saravanakumar, Balasubramaniam & Lee, Gae Myoung & Jeong, Ji Hyun & Kim, Sang-Jae, 2017. "Worm structure piezoelectric energy harvester using ionotropic gelation of barium titanate-calcium alginate composite," Energy, Elsevier, vol. 118(C), pages 1146-1155.
    6. Khandelwal, Gaurav & Chandrasekhar, Arunkumar & Alluri, Nagamalleswara Rao & Vivekananthan, Venkateswaran & Maria Joseph Raj, Nirmal Prashanth & Kim, Sang-Jae, 2018. "Trash to energy: A facile, robust and cheap approach for mitigating environment pollutant using household triboelectric nanogenerator," Applied Energy, Elsevier, vol. 219(C), pages 338-349.
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