Prototype wind and solar smart grid controller is the brains behind this project. There are 48 pages in this book, with two table, 17 figures, and 37 numbered references. April 2022 for a Bachelor of Science in Technical Education with Specialization in Electrical Engineering.

Darboe, Fanding; Sale, Abubakar; Sanyang, Binta; Ayshan, Nabil Aameen Qaid

IUT Repository Home
→
Technical and Vocational Education (TVE)
→
Thesis
→
Undergraduate
→
2022
→
View Item

dc.contributor.author	Darboe, Fanding
dc.contributor.author	Sale, Abubakar
dc.contributor.author	Sanyang, Binta
dc.contributor.author	Ayshan, Nabil Aameen Qaid
dc.date.accessioned	2023-04-06T06:05:53Z
dc.date.available	2023-04-06T06:05:53Z
dc.date.issued	2022-05-01
dc.identifier.citation	[1] n. fontes, a. roque, and j. maia, "micro generation—solar and wind hybrid system," in 2008 5th international conference on the european electricity market, 2008: ieee, pp. 1-5. [2] r. min et al., "energy-centric enabling technologies for wireless sensor networks," ieee wireless communication magazine, vol. 9, no. 4, pp. 28-39, 2002. [3] a. tascikaraoglu, m. uzunoglu, m. tanrioven, a. r. boynuegri, and o. elma, "smart grid-ready concept of a smart home prototype: a demonstration project in ytu," in 4th international conference on power engineering, energy and electrical drives, 2013: ieee, pp. 1568-1573. [4] p. abichandani, w. mcintyre, w. fligor, and d. lobo, "solar energy education through a cloud-based desktop virtual reality system," ieee access, vol. 7, pp. 147081-147093, 2019. [5] p.-a. hsiung, "smart grid design modeling and prototyping," in proceedings of 3rd international conference on reliability, infocom technologies and optimization, 2014: ieee, pp. 1-1. [6] a. pena-bello, e. barbour, m. gonzalez, m. patel, and d. parra, "optimized pv-coupled battery systems for combining applications: impact of battery technology and geography," renewable and sustainable energy reviews, vol. 112, pp. 978-990, 2019. [7] y. e. garcía-vera, r. dufo-lópez, and j. l. bernal-agustín, "optimization of isolated hybrid microgrids with renewable energy based on different battery models and technologies," energies, vol. 13, no. 3, p. 581, 2020. [8] r. carapellucci and l. giordano, "modeling and optimization of an energy generation island based on renewable technologies and hydrogen storage systems," international journal of hydrogen energy, vol. 37, no. 3, pp. 2081-2093, 2012. [9] p. tavner, j. xiang, and f. spinato, "reliability analysis for wind turbines," wind energy: an international journal for progress and applications in wind power conversion technology, vol. 10, no. 1, pp. 1-18, 2007. [10] s. shokrzadeh, m. j. jozani, and e. bibeau, "wind turbine power curve modeling using advanced parametric and nonparametric methods," ieee transactions on sustainable energy, vol. 5, no. 4, pp. 1262-1269, 2014. [11] m. a. hasan and s. k. parida, "an overview of solar photovoltaic panel modeling based on analytical and experimental viewpoint," renewable and sustainable energy reviews, vol. 60, pp. 75-83, 2016. [12] o. breitenstein, p. altermatt, k. ramspeck, and a. schenk, "the origin of ideality factors n> 2 of shunts and surfaces in the dark iv curves of si solar cells," in proceedings of the 21st european photovoltaic solar energy conference, 2006: citeseer, pp. 625-628. [13] m. acevedo, "arduino based hybrid mppt controller for wind and solar," university of north texas, 2017. [14] a. c.-c. hua and b. z.-w. syue, "charge and discharge characteristics of lead-acid battery and lifepo4 battery," in the 2010 international power electronics conference-ecce asia-, 2010: ieee, pp. 1478-1483. [15] g. dileep, "a survey on smart grid technologies and applications," renewable energy, vol. 146, pp. 2589-2625, 2020. [16] m. zangeneh, e. aghajari, and m. forouzanfar, "design and implementation of an intelligent multiinput multi-output sugeno fuzzy logic controller for managing energy resources in a hybrid renewable energy power system based on arduino boards," soft computing, vol. 26, no. 3, pp. 1459-1473, 2022. [17] m. taylor, p. ralon, and a. ilas, "the power to change: solar and wind cost reduction potential to 2025. 2016," international renewable energy agency. 38 [18] f. kreith and s. krumdieck, principles of sustainable energy systems. crc press, 2013. [19] m. lelie et al., "battery management system hardware concepts: an overview," applied sciences, vol. 8, no. 4, p. 534, 2018. [20] h. i. jager, r. a. efroymson, j. j. opperman, and m. r. kelly, "spatial design principles for sustainable hydropower development in river basins," renewable and sustainable energy reviews, vol. 45, pp. 808-816, 2015. [21] r. kerley, "small-scale hybrid alternative energy maximizer for wind turbines and photovoltaic panels," 2011. [22] p. sullivan, "applying the principles of sustainable farming," national center for appropriate technology, http://attra. ncat. org/attra-pub/pdf/transition. pdf (accessed january 2011), 2003. [23] a. h. al-badi, r. ahshan, n. hosseinzadeh, r. ghorbani, and e. hossain, "survey of smart grid concepts and technological demonstrations worldwide emphasizing on the oman perspective," applied system innovation, vol. 3, no. 1, p. 5, 2020. [24] l. b. uslu, l. a. karakan, and a. p. r. şihab, "monocrystalline photovoltaic test set design." [25] n. mendis, k. m. muttaqi, s. sayeef, and s. perera, "standalone operation of wind turbine-based variable speed generators with maximum power extraction capability," ieee transactions on energy conversion, vol. 27, no. 4, pp. 822-834, 2012. [26] d. c. leslie et al., "frequency-specific flow control in microfluidic circuits with passive elastomeric features," nature physics, vol. 5, no. 3, pp. 231-235, 2009. [27] t. fowler and e. nalder, "tag archives: alternative energy," money, vol. 10, p. 59pm, 2010. [28] b. belvedere, m. bianchi, a. borghetti, c. a. nucci, m. paolone, and a. peretto, "a microcontrollerbased power management system for standalone microgrids with hybrid power supply," ieee transactions on sustainable energy, vol. 3, no. 3, pp. 422-431, 2012. [29] j.-l. levant, m. ramdani, and r. perdriau, "icem modelling of microcontroller current activity," microelectronics journal, vol. 35, no. 6, pp. 501-507, 2004. [30] m. fezari and a. al dahoud, "integrated development environment “ide” for arduino," wsn applications, pp. 1-12, 2018. [31] l. müller, m. mohammed, and j. w. kimball, "using the arduino uno to teach digital control of power electronics," in 2015 ieee 16th workshop on control and modeling for power electronics (compel), 2015: ieee, pp. 1-8. [32] e. siegenthaler, y. bochud, p. bergamin, and p. wurtz, "reading on lcd vs e‐ink displays: effects on fatigue and visual strain," ophthalmic and physiological optics, vol. 32, no. 5, pp. 367-374, 2012. [33] g. zhou, j. xu, and y. jin, "improved digital peak current predictive control for switching dc-dc converters," iet power electronics, vol. 4, no. 2, pp. 227-234, 2011. [34] z. dzulfikri, n. nuryanti, and y. erdani, "design and implementation of artificial neural networks to predict wind directions on controlling yaw of wind turbine prototype," journal of robotics and control (jrc), vol. 1, no. 1, pp. 20-26, 2020. [35] a. b. northmore and s. l. tighe, "performance modelling of a solar road panel prototype using finite element analysis," international journal of pavement engineering, vol. 17, no. 5, pp. 449- 457, 2016. [36] g. n. aretoulis, d. c. angelides, g. p. kalfakakou, g. s. fotiadis, and k. i. anastasiadis, "a prototype system for the prediction of final cost in construction projects," operational research, vol. 6, no. 3, pp. 323-332, 2006. [37] o. chocron, u. prieur, and l. pino, "a validated feasibility prototype for auv reconfigurable magnetic coupling thruster," ieee/asme transactions on mechatronics, vol. 19, no. 2, pp. 642-650, 2013.	en_US
dc.identifier.uri	http://hdl.handle.net/123456789/1816
dc.description	Supervised by Prof. Dr. Md. Rezaul Hoque Khan, Department of Electrical and Electronic Engineering(EEE), Islamic University of Technology(IUT), Board Bazar, Gazipur-1704, Bangladesh. Submitted in Partial Fulfillment of the Requirements for the Degree of Bachelor of Science in Technical Education with a Specialization in Electrical and Electronic Engineering(EEE),.	en_US
dc.description.abstract	Prototype wind and solar smart grid controller is the brains behind this project. There are 48 pages in this book, with two table, 17 figures, and 37 numbered references. April 2022 for a Bachelor of Science in Technical Education with Specialization in Electrical Engineering.	en_US
dc.language.iso	en	en_US
dc.publisher	Departmental of Technical and Vocational Education(TVE), Islamic University of Technology(IUT), Board Bazar, Gazipur-1704, Bangladesh	en_US
dc.subject	A Smart Grid Prototype has been developed with regards to two renewable energy sources; Solar and Wind. Arduino base was used determine maximum power point tracker for the two renewable energy sources. Submitted in partial fulfillment of the requirements for the Degree of BSc.TE (EEE)	en_US
dc.title	Prototype wind and solar smart grid controller is the brains behind this project. There are 48 pages in this book, with two table, 17 figures, and 37 numbered references. April 2022 for a Bachelor of Science in Technical Education with Specialization in Electrical Engineering.	en_US
dc.type	Thesis	en_US