Energy production using solar-powered electrolyzer and hydrogen fuel cell / Teoh Wei Hern... [et al.]

This study presented the implementation of a small-scale (50 W) solar energy harvesting system coupled with an electrolyzer and proton exchange membrane (PEM) fuel cell. The energy from the solar panel would be utilized by the electrolyzer to produce hydrogen gas. The hydrogen gas would be used,...

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Main Authors:	Teoh, Wei Hern, Abdullah, Samihah, Abdul Hamid, Shabinar, Fadhlullah, Salahuddin Yusuf
Format:	Article
Language:	English
Published:	Universiti Teknologi MARA Cawangan Pulau Pinang 2019
Subjects:	Electric power distribution. Electric power transmission Applications of electric power Electric apparatus and materials. Electric circuits. Electric networks
Online Access:	http://ir.uitm.edu.my/id/eprint/28901/ http://ir.uitm.edu.my/id/eprint/28901/1/28901.pdf

id	uitm-28901
recordtype	eprints
spelling	uitm-289012020-03-19T06:16:07Z http://ir.uitm.edu.my/id/eprint/28901/ Energy production using solar-powered electrolyzer and hydrogen fuel cell / Teoh Wei Hern... [et al.] Teoh, Wei Hern Abdullah, Samihah Abdul Hamid, Shabinar Fadhlullah, Salahuddin Yusuf Electric power distribution. Electric power transmission Applications of electric power Electric apparatus and materials. Electric circuits. Electric networks This study presented the implementation of a small-scale (50 W) solar energy harvesting system coupled with an electrolyzer and proton exchange membrane (PEM) fuel cell. The energy from the solar panel would be utilized by the electrolyzer to produce hydrogen gas. The hydrogen gas would be used, in turn, by the PEM fuel cell to generate electricity which supports both DC and AC load. Excess energy from the solar panel is also used to charge the lead-acid backup battery. Analysis of the system showed that 400 mL of hydrogen gas could be produced within every 17 minutes in optimal conditions; between 11 am until 4 pm with bright sunlight. For every 400 mL of hydrogen gas, the PEM fuel cell could sustain continuous operation of a 5V 500 mA DC load for 95 seconds. Theoretically, more than 7000 mL of hydrogen gas could be produced within 5 hours in strong sunlight, which could power up a 50 mA and 500 mA load for 4.7 hours and 28 minutes respectively, during evening or night operations. The proposed system could complement the traditional battery-based storage system while remaining as a clean source of energy production. Universiti Teknologi MARA Cawangan Pulau Pinang 2019-06 Article PeerReviewed text en http://ir.uitm.edu.my/id/eprint/28901/1/28901.pdf Teoh, Wei Hern and Abdullah, Samihah and Abdul Hamid, Shabinar and Fadhlullah, Salahuddin Yusuf (2019) Energy production using solar-powered electrolyzer and hydrogen fuel cell / Teoh Wei Hern... [et al.]. ESTEEM Academic Journal, 15. pp. 10-17. ISSN 2289-4934
repository_type	Digital Repository
institution_category	Local University
institution	Universiti Teknologi MARA
building	UiTM Institutional Repository
collection	Online Access
language	English
topic	Electric power distribution. Electric power transmission Applications of electric power Electric apparatus and materials. Electric circuits. Electric networks
spellingShingle	Electric power distribution. Electric power transmission Applications of electric power Electric apparatus and materials. Electric circuits. Electric networks Teoh, Wei Hern Abdullah, Samihah Abdul Hamid, Shabinar Fadhlullah, Salahuddin Yusuf Energy production using solar-powered electrolyzer and hydrogen fuel cell / Teoh Wei Hern... [et al.]
description	This study presented the implementation of a small-scale (50 W) solar energy harvesting system coupled with an electrolyzer and proton exchange membrane (PEM) fuel cell. The energy from the solar panel would be utilized by the electrolyzer to produce hydrogen gas. The hydrogen gas would be used, in turn, by the PEM fuel cell to generate electricity which supports both DC and AC load. Excess energy from the solar panel is also used to charge the lead-acid backup battery. Analysis of the system showed that 400 mL of hydrogen gas could be produced within every 17 minutes in optimal conditions; between 11 am until 4 pm with bright sunlight. For every 400 mL of hydrogen gas, the PEM fuel cell could sustain continuous operation of a 5V 500 mA DC load for 95 seconds. Theoretically, more than 7000 mL of hydrogen gas could be produced within 5 hours in strong sunlight, which could power up a 50 mA and 500 mA load for 4.7 hours and 28 minutes respectively, during evening or night operations. The proposed system could complement the traditional battery-based storage system while remaining as a clean source of energy production.
format	Article
author	Teoh, Wei Hern Abdullah, Samihah Abdul Hamid, Shabinar Fadhlullah, Salahuddin Yusuf
author_facet	Teoh, Wei Hern Abdullah, Samihah Abdul Hamid, Shabinar Fadhlullah, Salahuddin Yusuf
author_sort	Teoh, Wei Hern
title	Energy production using solar-powered electrolyzer and hydrogen fuel cell / Teoh Wei Hern... [et al.]
title_short	Energy production using solar-powered electrolyzer and hydrogen fuel cell / Teoh Wei Hern... [et al.]
title_full	Energy production using solar-powered electrolyzer and hydrogen fuel cell / Teoh Wei Hern... [et al.]
title_fullStr	Energy production using solar-powered electrolyzer and hydrogen fuel cell / Teoh Wei Hern... [et al.]
title_full_unstemmed	Energy production using solar-powered electrolyzer and hydrogen fuel cell / Teoh Wei Hern... [et al.]
title_sort	energy production using solar-powered electrolyzer and hydrogen fuel cell / teoh wei hern... [et al.]
publisher	Universiti Teknologi MARA Cawangan Pulau Pinang
publishDate	2019
url	http://ir.uitm.edu.my/id/eprint/28901/ http://ir.uitm.edu.my/id/eprint/28901/1/28901.pdf
first_indexed	2023-09-18T23:20:48Z
last_indexed	2023-09-18T23:20:48Z
_version_	1777419417933578240

Energy production using solar-powered electrolyzer and hydrogen fuel cell / Teoh Wei Hern... [et al.]

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