Wood-Plastic Composites Integration for Triboelectric Nanogenerator Electricity Generation

Access to electricity in underdeveloped communities is particularly crucial in improving the living standards of people and alleviating poverty by promoting sustainable development. This study deals with the exploration of incorporating wood-plastic composite (WPC) – specifically wood pulp (W) and h...

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Main Authors:	Park, Hanbyeol, Dimaporo, Razamala Yashna F., Emperado, Sophia Maureen A., Pangilinan, Anton Jefferson L., Gumangan, Juan Carlo T.
Format:	text
Published:	Animo Repository 2024
Subjects:	triboelectric wood-plastic composite energy mechanical energy conversion renewable energy Energy Systems Other Materials Science and Engineering Polymer and Organic Materials
Online Access:	https://animorepository.dlsu.edu.ph/sinaya/vol3/iss1/1 https://animorepository.dlsu.edu.ph/context/sinaya/article/1083/viewcontent/_Final_Proof__S_T_Manuscript_1.pdf
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Institution:	De La Salle University

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spelling	oai:animorepository.dlsu.edu.ph:sinaya-10832024-12-17T08:37:35Z Wood-Plastic Composites Integration for Triboelectric Nanogenerator Electricity Generation Park, Hanbyeol Dimaporo, Razamala Yashna F. Emperado, Sophia Maureen A. Pangilinan, Anton Jefferson L. Gumangan, Juan Carlo T. Access to electricity in underdeveloped communities is particularly crucial in improving the living standards of people and alleviating poverty by promoting sustainable development. This study deals with the exploration of incorporating wood-plastic composite (WPC) – specifically wood pulp (W) and high-density polyethylene (H) – into triboelectric nanogenerator (TENG) flooring system to convert mechanical energy to electrical energy, promoting sustainable energy, reducing greenhouse gas emissions, improving the quality of life, and serving as feasible flooring tiles. Two types of TENG tiles were prepared by using different WPC ratios: 30W:70H and 70W:30H. A static bending test was conducted to assess the flexural strength of the TENGs, and a generated voltage test was performed by stepping on the TENGs several times and using a multimeter to measure the generated voltage. The 30W:70H TENGs had a significantly higher resistance to stress, with 18.0 MPa (SD=2.42), compared with that of 70W:30H TENGs, which had 8.07 MPa (SD=3.04) [t(8) = -5.74, p < 0.001]. However, the 30W:70H TENGs (overall M = 0.240 volts, SD = 0.051) generated slightly lower voltage than the 70W:30H TENGs (overall M = 0.265 volts, SD = 0.128), but no significant difference was concluded [t(8) = -0.415, p = 0.689]. The findings of this experiment allow for greater insight with respect to both compatibility and the potential applicability of the components in the real world. Other materials and parameters that could influence the performance of TENG tiles should be investigated, and the tiles should be tested under real-world conditions to obtain more accurate and practical performance data. 2024-12-20T08:00:00Z text application/pdf https://animorepository.dlsu.edu.ph/sinaya/vol3/iss1/1 info:doi/10.59588/3027-9283.1083 https://animorepository.dlsu.edu.ph/context/sinaya/article/1083/viewcontent/_Final_Proof__S_T_Manuscript_1.pdf Sinaya: A Philippine Journal for Senior High School Teachers and Students Animo Repository triboelectric wood-plastic composite energy mechanical energy conversion renewable energy Energy Systems Other Materials Science and Engineering Polymer and Organic Materials
institution	De La Salle University
building	De La Salle University Library
continent	Asia
country	Philippines Philippines
content_provider	De La Salle University Library
collection	DLSU Institutional Repository
topic	triboelectric wood-plastic composite energy mechanical energy conversion renewable energy Energy Systems Other Materials Science and Engineering Polymer and Organic Materials
spellingShingle	triboelectric wood-plastic composite energy mechanical energy conversion renewable energy Energy Systems Other Materials Science and Engineering Polymer and Organic Materials Park, Hanbyeol Dimaporo, Razamala Yashna F. Emperado, Sophia Maureen A. Pangilinan, Anton Jefferson L. Gumangan, Juan Carlo T. Wood-Plastic Composites Integration for Triboelectric Nanogenerator Electricity Generation
description	Access to electricity in underdeveloped communities is particularly crucial in improving the living standards of people and alleviating poverty by promoting sustainable development. This study deals with the exploration of incorporating wood-plastic composite (WPC) – specifically wood pulp (W) and high-density polyethylene (H) – into triboelectric nanogenerator (TENG) flooring system to convert mechanical energy to electrical energy, promoting sustainable energy, reducing greenhouse gas emissions, improving the quality of life, and serving as feasible flooring tiles. Two types of TENG tiles were prepared by using different WPC ratios: 30W:70H and 70W:30H. A static bending test was conducted to assess the flexural strength of the TENGs, and a generated voltage test was performed by stepping on the TENGs several times and using a multimeter to measure the generated voltage. The 30W:70H TENGs had a significantly higher resistance to stress, with 18.0 MPa (SD=2.42), compared with that of 70W:30H TENGs, which had 8.07 MPa (SD=3.04) [t(8) = -5.74, p < 0.001]. However, the 30W:70H TENGs (overall M = 0.240 volts, SD = 0.051) generated slightly lower voltage than the 70W:30H TENGs (overall M = 0.265 volts, SD = 0.128), but no significant difference was concluded [t(8) = -0.415, p = 0.689]. The findings of this experiment allow for greater insight with respect to both compatibility and the potential applicability of the components in the real world. Other materials and parameters that could influence the performance of TENG tiles should be investigated, and the tiles should be tested under real-world conditions to obtain more accurate and practical performance data.
format	text
author	Park, Hanbyeol Dimaporo, Razamala Yashna F. Emperado, Sophia Maureen A. Pangilinan, Anton Jefferson L. Gumangan, Juan Carlo T.
author_facet	Park, Hanbyeol Dimaporo, Razamala Yashna F. Emperado, Sophia Maureen A. Pangilinan, Anton Jefferson L. Gumangan, Juan Carlo T.
author_sort	Park, Hanbyeol
title	Wood-Plastic Composites Integration for Triboelectric Nanogenerator Electricity Generation
title_short	Wood-Plastic Composites Integration for Triboelectric Nanogenerator Electricity Generation
title_full	Wood-Plastic Composites Integration for Triboelectric Nanogenerator Electricity Generation
title_fullStr	Wood-Plastic Composites Integration for Triboelectric Nanogenerator Electricity Generation
title_full_unstemmed	Wood-Plastic Composites Integration for Triboelectric Nanogenerator Electricity Generation
title_sort	wood-plastic composites integration for triboelectric nanogenerator electricity generation
publisher	Animo Repository
publishDate	2024
url	https://animorepository.dlsu.edu.ph/sinaya/vol3/iss1/1 https://animorepository.dlsu.edu.ph/context/sinaya/article/1083/viewcontent/_Final_Proof__S_T_Manuscript_1.pdf
_version_	1819113610960437248

Wood-Plastic Composites Integration for Triboelectric Nanogenerator Electricity Generation

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