Piezoelectricity as a Sustainable alternative to the Energy of Small Products | ||||
International Design Journal | ||||
Article 30, Volume 14, Issue 1 - Serial Number 59, January and February 2024, Page 439-454 PDF (1.62 MB) | ||||
Document Type: Original Article | ||||
DOI: 10.21608/idj.2023.250248.1100 | ||||
View on SCiNiTO | ||||
Authors | ||||
Ahmed Mohamed zayed 1; Shorok Mohamed Herbid2 | ||||
1Industrial Design Department, Faculty of Applied Arts, Damietta University, Egypt. | ||||
2Faculty of Applied Arts, Damietta University, Department of Industrial Design. | ||||
Abstract | ||||
The use of new and renewable energies is considered one of the most important methods of product sustainability due to its ability to supply the products with continuous sources of energy, and not having a negative impact on the environment, adding new characteristics to the products such as light weight, speed, accuracy, or Aesthetic appearance, and the ability to use in uninhabited areas. Piezoelectric energy is also considered one of the most important new and renewable energies that can contribute to achieving sustainability due to its dependence on natural materials. As a result, global interest has begun to employ it, especially with regard to generating energy through leg movement or by hand. Through breathing or blood pressure, body temperature, movement of the fingers and limbs, in addition to building energy harvesting systems...etc. The problem of the current research lies in the consumption of small products from many traditional energy sources during their life cycle, which causes harm to the environment as a result of the manufacture of these sources which turns into harmful waste that must be treated after the end of its lifespan, also Traditional energy sources increase the size of relatively small products. The research has led to a group of products which operate through piezoelectric energy, and characterized by its accuracy and speed of response, which helps in reducing its size, cost and increasing its efficiency, lifespan, and contributes to achieving sustainability by replacing traditional energy sources with a natural environmental source made of quartz. | ||||
Keywords | ||||
New and Renewable Energies; piezoelectricity; Energy harvesting; Sustainability; energy of small products | ||||
Supplementary Files
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References | ||||
1- Abidin, N. A. (2020). The simulation analysis of piezoelectric transducer with multi-array configuration. Journal of Physics, 1432(1), 012-042.
2- APC International piezo. (2023, 7). PIEZOELECTRICITY. Retrieved from www.americanpiezo.com: https://www.americanpiezo.com/knowledge-center/piezo-theory/piezoelectricity.html
3- Churchill, D. L. (2003, July). Strain energy harvesting for wireless sensor networks. In Smart structures and materials 2003: smart electronics, MEMS, BioMEMS, and nanotechnology, 5055, 319-327. Retrieved from http://www.ittc.ku.edu/~callen/energy_harvesting/Churchill2003SPIEpp319-327.pdf
4- Curie, J. &. (1880). Développement, par pression, de l’électricité polaire dans les cristaux hémièdres à faces inclinées.
5- E. Häsler, L. S. (1984). Implantable physiological power supply with PVDF film. Ferroelectrics, 60(1), 277-282.
6- Egusa, S. W. (2010). Multimaterial piezoelectric fibres. Nature materials, 9(8), 643-648.
7- Fukada, E. (1992). Bioelectrets and biopiezoelectricity. IEEE transactions on electrical insulation, 27(4), 813-819.
8- Fukada, E. (1998 ). New piezoelectric polymers. Japanese journal of applied physics, 37(5S), 2775. doi:10.1143/JJAP.37.2775
9- Granstrom, J. F. (2007). Energy harvesting from a backpack instrumented with piezoelectric shoulder straps. Smart Materials and Structures, 16(5), 1810.
10- Henderson, T. (2009, September 3). Power generating shoes. Retrieved from printedelectronicsworld: https://www.printedelectronicsworld.com/articles/1653/power-generating-shoes
11- Hunstig, M. (2017, February). Piezoelectric Inertia Motors—A Critical Review of History, Concepts, Design, Applications, and Perspectives. Actuators, 6(1), 7.
12- Kawai, H. (1969). The piezoelectricity of poly (vinylidene fluoride). Japanese journal of applied physics, 8(7), 975.
13- Kholkin, A. A. (2010). Strong piezoelectricity in bioinspired peptide nanotubes. ACS nano, 4(2), 610-614.
14- Kim, J. H. (2010). Electrifying! Beautiful, Innovative & Radiant. Retrieved from michelinchallengedesign: https://www.michelinchallengedesign.com/the-challenge-archives/2010-electrifying/2010-showcase-of-selected-entrants/p-eco-by-jung-hoon-kim-south-korea/
15- Li, X., & Strezov, V. (2014). Modelling piezoelectric energy harvesting potential in an educational building. Energy Conversion and Management, 85, 435-442.
16- Lombard, L. P., Ortiz, J., & Pout, C. (2008). A review on buildings energy consumption information. Energy and buildings, 40(3), 394-398.
17- Maestre, S. (2022, Jan 24). What is Piezoelectric Effect? Retrieved from www.circuitbread.com: https://www.circuitbread.com/ee-faq/what-is-piezoelectric-effect
18- Martin, A. J. (1941). Tribo-electricity in wool and hair. Proceedings of the Physical Society, 53(2), 186. doi:10.1088/0959-5309/53/2/310
19- Mathur, S. C. (1984). Piezoelectric properties and ferroelectric hysteresis effects in uniaxially stretched nylon‐11 films. Journal of applied physics, 56(9), 2419-2425. doi:https://doi.org/10.1063/1.334294
20- Najini, H., & Muthukumaraswamy, S. A. (2017). Piezoelectric energy generation from vehicle traffic with technoeconomic analysis. Journal of Renewable Energy.
21- Rajabi, A. H., Jaffe, M., & Arinzeh, T. L. (2015). Piezoelectric materials for tissue regeneration: A review. Acta biomaterialia, 24, 12-23. Retrieved from https://www.sciencedirect.com/science/article/pii/S1742706115300167?casa_token=_BQ3u-ywLt4AAAAA:qSKUBq54dW0qr4ExK2cLuwGXZhkB-nv9e1R5N9KuFyoo6hbYsYK4FhMcdRD8oJL7OgbrC88Uw0r6
22- Rajabi, A. H., Jaffe, M., & Arinzeh, T. L. (2015). Piezoelectric materials for tissue regeneration: A review. Acta biomaterialia, 24, 12-23.
23- Robledo, E. (2023, FEBRUARY 12). How Piezoelectricity Works to Make Crystals Conduct Electric Current. Retrieved from autodesk: https://www.autodesk.com/products/fusion-360/blog/piezoelectricity/
24- Sekhar, B. C. (2021). Piezoelectricity and Its Applications. In D. R. Sahu, Multifunctional Ferroelectric Materials. doi:10.5772/intechopen.96154
25- Shenck, N. (1999). A demonstration of useful electric energy generation from piezoceramics in a shoe. Doctoral dissertation, Massachusetts Institute of Technology.
26- Shivali, M. S. (2022). A BRIEF NOTE ON PRINCIPLE, MECHANISM AND APPLICATIONS OF PIEZOELECTRIC MATERIALS. An Interdisciplinary Journal, 5. Retrieved from chrome-extension://efaidnbmnnnibpcajpcglclefindmkaj/https://ggscw.ac.in/Downloads/Article1.pdf
27- Singh, P. K., Kaur, G. A., Shandilya, M., Rana, P., Rai, R., Mishra, Y. K., . . . Tiwari, A. (2023). Trends in Piezoelectric Nanomaterials towards Green Energy Scavenging Nanodevices. Materials Today Sustainability, 100583.
28- Smith, M., & Kar-Narayan, S. (2022). Piezoelectric polymers: Theory, challenges and opportunities. International Materials Reviews, 67(1), 65-88. doi:https://doi.org/10.1080/09506608.2021.1915935
29- Starner, T. (1996). Human-powered wearable computing. IBM systems Journal, 35(3.4), 618-629.
30- United Nations. (2023). Renewable energy – powering a safer future. Retrieved from un.org: https://www.un.org/en/climatechange/raising-ambition/renewable-energy
31- Vatansever, D. S. (2012). Alternative resources for renewable energy: piezoelectric and photovoltaic smart structures. Global Warming-Impacts and Future Perspective, 263.
32- Victor, NY. (2012, Aug 22). New Scale awarded US patent for reduced-voltage linear motor system. Retrieved from new scale technologies: https://www.newscaletech.com/pr-new-scale-awarded-us-patent-reduced-voltage-linear-motor-system/
Yuan, F. (2020). Application of Piezoelectric Ceramics in Industrial Products. Frontier Computing: Theory, Technologies and Applications (FC 2019) (pp. 807-813). Singapore: Springer. | ||||
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