An Exergoeconomic Evaluation of an Innovative Polygeneration System Using a Solar-Driven Rankine Cycle Integrated with the Al-Qayyara Gas Turbine Power Plant and the Absorption Refrigeration Cycle

Talal, Wadah; Akroot, Abdulrazzak

doi:10.3390/machines12020133

Cited by 3 publications

(2 citation statements)

References 34 publications

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“…Efforts to find cleaner and more efficient fuels for diesel engines have prompted the investigation of different additives and mixtures. Biodiesel generated from sunflower oil has become an attractive alternative since it is sustainable and can reduce greenhouse gas emissions significantly [1,2]. Researchers are using nanotechnology, namely copper oxide nanoparticles, to improve the efficiency of biodiesel mixes [3,4].…”

Section: Introductionmentioning

confidence: 99%

Enhancing Diesel Engine Performance with Different Concentrations of Copper Oxide Nanoparticles in Biodiesel Blends

Akroot,

Kareem,

Alfaris

et al. 2024

IJDNE

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Section: Introductionmentioning

confidence: 99%

Enhancing Diesel Engine Performance with Different Concentrations of Copper Oxide Nanoparticles in Biodiesel Blends

Akroot,

Kareem,

Alfaris

et al. 2024

IJDNE

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“…Adibhatla and Kaushik [31] found that integrating solar energy into a natural gas CCPP using DSG and PTCs increased output by 7.84%, improved efficiencies to 53.79% and 27.39%, and reduced electricity costs from 0.074 to 0.067 USD/kWh. Talal et al [32,33] discussed the advantages of integrating solar thermal energy with gas turbines in Iraq, highlighting the economic and efficiency gains over traditional systems and advocating for adopting integrated solar combined cycle (ISCC) plants to improve Iraq's energy infrastructure. Dabwan and Pei [34] assessed traditional and solar-integrated gas turbine trigeneration plants, finding that a configuration combining a 126-hectare solar field with a 130 MWe plant cut CO 2 emissions by 114 kilotonnes and set energy prices at 5.75 USD/kWh.…”

Section: Introductionmentioning

confidence: 99%

Techno-Economic and Environmental Impact Analysis of a 50 MW Solar-Powered Rankine Cycle System

Akroot,

Al Shammre

2024

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The interest in combined heat and solar power (CHP) systems has increased due to the growing demand for sustainable energy with low carbon emissions. An effective technical solution to address this requirement is using a parabolic trough solar collector (PTC) in conjunction with a Rankine cycle (RC) heat engine. The solar-powered Rankine cycle (SPRC) system is a renewable energy technology that can be relied upon for its high efficiency and produces clean energy output. This study describes developing a SPRC system specifically for electricity generation in Aden, Yemen. The system comprises parabolic trough collectors, a thermal storage tank, and a Rankine cycle. A 4E analysis of this system was theoretically investigated, and the effects of various design conditions, namely the boiler’s pinch point temperature and steam extraction from the high-pressure turbine, steam extraction from the intermediate-pressure turbine, and condenser temperature, were studied. Numerical simulations showed that the system produces a 50 MW net. The system’s exergetic and energy efficiencies are 30.7% and 32.4%. The planned system costs 2509 USD/h, the exergoeconomic factor is 79.43%, and the system’s energy cost is 50.19 USD/MWh. The system has a 22.47 kg/MWh environmental carbon footprint. It is also observed that the performance of the cycle is greatly influenced by climatic circumstances. Raising the boiler’s pinch point temperature decreases the system’s performance and raises the environmental impact.

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Economic and Technical Assessing the Hybridization of Solar Combined Cycle System with Fossil Fuel and Rock Bed Thermal Energy Storage in Neom City

Akroot,

Al Shammre

2024

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Rising energy demands, the depletion of fossil fuels, and their environmental impact necessitate a shift towards sustainable power generation. Concentrating solar power (CSP) offers a promising solution. This study examines a hybridization of a combined cycle power plant (CCPP) based on solar energy with fossil fuel and energy storage in rock layers to increase Saudi Arabia’s electricity production from renewable energy. The fuel is used to keep the temperature at the inlet of the gas turbine at 1000 °C, ensuring the power produced by the Rankine cycle remains constant. During the summer, the sun is the main source of power generation, whereas in the winter, reliance on fuel increases significantly. The Brayton cycle operates for 10 h during peak solar radiation periods, storing exhaust heat in rock beds. For the remaining 14 h of the day, this stored heat is discharged to operate the Rankine steam cycle. Simulations and optimizations are performed, and the system is evaluated using a comprehensive 4E analysis (energy, exergy, exergoconomic, and environmental) alongside a sustainability assessment. A parametric evaluation examines the effect of key factors on system performance. The rock bed storage system compensates for solar intermittency, enabling power generation even without sunlight. The study reveals that the system generated 12.334 MW in June, achieving an energy efficiency of 37% and an exergy efficiency of 40.35%. The average electricity cost during this period was 0.0303 USD/kWh, and the carbon footprint was 0.108 kg CO2/kWh. In contrast, during January, the system produced 13.276 MW with an energy efficiency of 37.91% and an exergy efficiency of 44.16%. The average electricity cost in January was 0.045 USD/kWh, and the carbon footprint was 0.1 kg CO2/kWh. Interestingly, solar energy played a significant role: it contributed 81.42% of the heat in June, while in January, it accounted for 46.77%. The reduced electricity costs during June are primarily attributed to the abundant sunshine, which significantly powered the system.

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An Exergoeconomic Evaluation of an Innovative Polygeneration System Using a Solar-Driven Rankine Cycle Integrated with the Al-Qayyara Gas Turbine Power Plant and the Absorption Refrigeration Cycle

Cited by 3 publications

References 34 publications

Enhancing Diesel Engine Performance with Different Concentrations of Copper Oxide Nanoparticles in Biodiesel Blends

Enhancing Diesel Engine Performance with Different Concentrations of Copper Oxide Nanoparticles in Biodiesel Blends

Techno-Economic and Environmental Impact Analysis of a 50 MW Solar-Powered Rankine Cycle System

Economic and Technical Assessing the Hybridization of Solar Combined Cycle System with Fossil Fuel and Rock Bed Thermal Energy Storage in Neom City

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