Thermodynamic analysis of a solar-based multi-generation system with hydrogen production

Öztürk, Murat; Dinçer, İbrahim

doi:10.1016/j.applthermaleng.2012.11.042

Cited by 133 publications

(32 citation statements)

References 17 publications

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“…Six outputs are generated, namely power, hot water, space heating, refrigeration, hydrogen, and oxygen. This case study is derived from the work by Ozturk and Dincer (2013b).…”

Section: Solar-based Multigeneration System With Hydrogen Productionmentioning

confidence: 99%

Multigeneration Systems

Dinçer

2014

Advanced Power Generation Systems

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“…Six outputs are generated, namely power, hot water, space heating, refrigeration, hydrogen, and oxygen. This case study is derived from the work by Ozturk and Dincer (2013b).…”

Section: Solar-based Multigeneration System With Hydrogen Productionmentioning

confidence: 99%

Multigeneration Systems

Dinçer

2014

Advanced Power Generation Systems

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“…Ozturk and Dincer [74] conducted a thermodynamic analysis of a solar based multigeneration system with hydrogen production. The solar based multigeneration considered for this analysis consists of four main sub systems: Rankine cycle, organic Rankine cycle, absorption cooling and heating, and hydrogen production and utilization.…”

Section: Multigeneration Energy Systemsmentioning

confidence: 99%

Performance Evaluation of Integrated Energy Systems

Ahmadi

Dinçer

Rosen

2014

Progress in Sustainable Energy Technologies: Generating Renewable Energy

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The current literature on integrated energy systems for various applications is discussed and how energy systems are integrated for multigeneration purposes is explained. Three integrated energy systems, including renewable and non-renewable ones, are considered to enhance the analyses. A micro-gas turbine integrated system is selected as the non-renewable system while biomass and ocean thermal energy conversion based energy systems are considered as the renewable options. Exergy analysis is conducted to determine the irreversibilities in each component and the system performance. Furthermore, economic and environmental impact assessments of the systems are conducted, and the results are presented for each integrated system. The results show that the integrated energy systems have higher exergy efficiency compared to single generation unit and that the integration results in reduction of greenhouse gases emission. The performances of the three systems are compared, and the results show that the choice and benefits of integrated systems strongly depends on the priorities of the designers and engineers.Keywords Energy · Exergy · Efficiency · Integrated energy system IntroductionEnergy use is directly linked to well-being and prosperity across the world. Meeting the growing demand for energy in a safe and environmentally responsible manner is an important challenge. A key driver of energy demand is the human desire to sustain and improve ourselves, our families and our communities. There are around 7 billion people on Earth and population growth will likely lead to an increase in energy demand, which depends on the adequacy of energy resources. Increasing population

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“…Dincer and Zamfirescu (2012) performed energy and exergy analyses of renewable energy-based multigeneration, considering several options for such products as electricity, heat, hot water, cooling, hydrogen and fresh water. Ozturk and Dincer (2012) conducted a thermodynamic analysis of a solar-based multigeneration system with hydrogen production. The solar-based multigeneration considered for this analysis consists of four main sub-systems: Rankine cycle, organic Rankine cycle, absorption cooling and heating, and hydrogen production and utilization.…”

Section: Introductionmentioning

confidence: 99%