Your search keyword '"Barhoumi, El Manaa"' showing total 4 results

1. Techno-economic analysis and optimization of hydrogen production from renewable hybrid energy systems: Shagaya renewable power plant-Kuwait.

Author

Hussam, Wisam K., Barhoumi, El Manaa, Abdul-Niby, M., and Sheard, Gregory J.

Subjects

*HYDROGEN as fuel, *GREENHOUSE gases, *RENEWABLE energy sources, *HYDROGEN analysis, *HYDROGEN production, *GREEN fuels, *CARBON emissions, *CARBON dioxide reduction

Abstract

The present study examines the potential for hydrogen production using the hybrid energy system at the Shagaya renewable power plant. Techno-economic and optimization analyses are used to identify the optimum configurations that reduce costs while increasing the renewable fraction and lowering greenhouse gas emissions. Three configurations were considered, exploring on- and off-grid combinations of photovoltaic solar (PV), wind turbine (WT), fuel cells and batteries. Integrating PV solar with wind power connected to the power grid was found to achieve the lowest levelized cost of energy of 0. 539 $ / kWh and a hydrogen production cost of 6. 85 $ / kg. However, for the stand-alone system where battery storage banks or fuel cells are used, the cost of hydrogen increases to more than 8. 0 $ / kg due to the larger capital cost of the system. The optimized system achieves annual green hydrogen production of 111 877 kg along with an annual carbon dioxide emission reduction of 14 819 kg. A sensitivity analysis proves that COE is more sensitive to PV price than wind turbines and electrolyzers. LCOE falls by 32.3% to 0.365 kWh when the PV unit price drops to 50%. The LCOE falls by 4% to 0.517 kWh when WT costs decrease by 50%. [Display omitted] • PV and wind integration connected to the power grid achieves low LCOE ($0.539/kWh) and hydrogen cost ($6.85/kg). • Battery and fuel cell systems increase hydrogen cost to more than $8.0/kg due to high capital expenses. • Optimized system produces 111,877 kg of green hydrogen annually, reducing CO 2 emissions by 14,819 kg. • LCOE is highly sensitive to PV cost. A 50% PV price drop reduces LCOE by 32.3% to $0.365/kWh. [ABSTRACT FROM AUTHOR]

Published

2024

2. Optimal sizing of photovoltaic systems based green hydrogen refueling stations case study Oman.

Author

Barhoumi, El Manaa, Okonkwo, Paul C., Ben Belgacem, Ikram, Zghaibeh, Manaf, and Tlili, Iskander

Subjects

*GREEN roofs, *PHOTOVOLTAIC power systems, *FUELING, *CARBON emissions, *ENERGY development, *ENERGY industries

Abstract

Green hydrogen reduces carbon dioxide emission, advances the dependency on fossil fuels and improves the economy of the energy sector, especially in developing countries. Hydrogen is required for the green transportation sector and many other industrial applications. However, the high cost of green hydrogen production reduces the fast development of renewable energy projects based on hydrogen production. So, sizing by optimization is required to determine the optimum solutions for green hydrogen production. In this context, this paper aims to analyze three methods that can be developed and implemented for the production of green hydrogen for refueling stations using photovoltaic (PV) systems. Techno-economic models are adopted to calculate the Levelized Hydrogen Cost (LHC) for the PV grid-connected system, stand-alone PV system with batteries, and stand-alone PV system with fuel cells. The photovoltaic systems based green hydrogen refueling stations are optimized using Homer software. The optimization results of the Net Profit Cost (NPC), and the LHC permit the comparison of the three cases and the selection of the optimal solution. The analysis has shown that a 3 MWp grid-connected PV system represents a promising green hydrogen production at an LHC of 5.5 €/kg. The system produces 58 615 kg of green hydrogen per year reducing carbon dioxide emission by 8209 kg per year. The LHC in the stand-alone PV system with batteries, and stand-alone PV system with fuel cells are 5.74 €/kg and 7.38 €/kg, respectively. • Levelized costs of hydrogen produced in photovoltaic refueling stations are analyzed. • Grid-connected photovoltaic system is an optimal solution providing green hydrogen. • Surplus of electricity produced in hydrogen stations is sold back to the power grid. • A 3 MWp photovoltaic system produces 58 615 kg of hydrogen at a levelized cost of 5.5 €/kg. [ABSTRACT FROM AUTHOR]

Published

2022

3. Analytical model for a techno-economic assessment of green hydrogen production in photovoltaic power station case study Salalah city-Oman.

Author

Zghaibeh, Manaf, Barhoumi, El Manaa, Okonkwo, Paul C., Ben Belgacem, Ikram, Beitelmal, Wesam Hassan, and Mansir, Ibrahim B.

Subjects

*SOLAR power plants, *HYDROGEN production, *RENEWABLE energy sources, *PHOTOVOLTAIC power systems, *INVESTMENT analysis, *HYDROGEN as fuel, *GREEN infrastructure, *STEAM reforming

Abstract

Hydrogen energy will play a credible role to reduce gas emissions in the transportation sector, the storage of energy, and other industrial applications. Moreover, the hydrogen produced from renewable energy sources allows to minimize greenhouse gas and increase the net profit of energy projects. This paper discusses the feasibility of the conversion of solar energy into hydrogen in a Photovoltaic Hydrogen Station (PVHS) in the south of Oman. Then, the sizing of different equipment and hydrogen production estimation in a 5 MWp PVHS is presented. The analysis of the investment cost (IC), the Net Profit (NP), and the Levelized Hydrogen Energy Cost (LHEC) are discussed to investigate the benefit of the project. The energy generated from the PV system and the produced hydrogen is calculated through an analytical model. The PVHS consists of 5 MWp PV panels connected to electrolyzers through maximum power point-controlled converters. The electrolyzers convert the electrical energy and the water into hydrogen. The hydrogen compressed and stored in special tanks can be used later in many industrial applications. The system produces about 90 910 kg of hydrogen per year with an IC of 5 301 760 €. The calculated LHEC is equal to 6.2 €/kg at an interest rate of 2%. The analysis has shown promising green hydrogen production projects in Oman. • The production of hydrogen using photovoltaic energy in Oman is analysed. • PV system consists of a promising process for green hydrogen production in Oman. • A 5 MWp photovoltaic power station produces around 90 910 kg of hydrogen per year. • The Levelized hydrogen cost produced in 5MWp PV station is 6.2 €/kg. • The breakeven point of the 5 MWp PV hydrogen station is 8 years for a hydrogen selling price of 10 € per kg. [ABSTRACT FROM AUTHOR]

Published

2022

4. Utilization of renewable hybrid energy for refueling station in Al-Kharj, Saudi Arabia.

Author

Okonkwo, Paul C., Mansir, Ibrahim B., Barhoumi, El Manaa, Emori, Wilfred, Radwan, Ahmed Bahgat, Shakoor, Rana A., Uzoma, Paul C., and Pugalenthi, M. Raja

Subjects

*RENEWABLE energy sources, *FUELING, *HYDROGEN as fuel, *HYDROGEN production, *POWER resources

Abstract

Hydrogen is one of the energy carriers that can be produced using different techniques. Combining multiple energy sources can enhance hydrogen production and meet other electrical demands. The hybrid arrangement allows the produced hydrogen to be stored and used when the electrical energy sources are not adequate. In this study, utilizing the meteorological data was investigated using HOMER (Hybrid Optimization of Multiple Energy Resources) software for the optimal solution. The results demonstrated that the "best-optimized system has 270 kW of photovoltaic (PV), 1 unit of 300 kW of wind turbine (WT), 500 kW of electrolyzer, 100 kg/L of the hydrogen tank, 70 units of 1 kWh lithium-ion battery, and 472 kW of the converter. The selected hybrid energy system has the lowest Levelized cost of energy (LCOE), Levelized cost of hydrogen (LCOH), and net present cost (NPC) of $/kg 0.6208, $/kg 9.34, and $ 484,360.00 respectively which judged the system to be the best choice for the proposed hydrogen project in AI-Kharj. This investigation will help stakeholders and policymakers optimize hybrid energy systems that economically meet the hydrogen production and refueling station demands of the AI-Kharj community. • Study of electrical energy generation for hydrogen production using renewable energy sources was performed. • Renewable energy sources are available in AI-Kharj as a result of the geographical location of the city. • HOMER software enhances the optimization and selection of the best hybrid energy system. • The selected hybrid energy system to meet the energy needs of the AI-Kharj has the lowest NPC, LCOE, and LCOH. [ABSTRACT FROM AUTHOR]

Published

2022