Numerical analysis of small scale axial and radial turbines for solar powered Brayton cycle application

Daabo, Ahmed M.; Mahmoud, Saad; Al-Dadah, Raya; Jubori, Ayad M. Al; Ennil, Ali Bhar

doi:10.1016/j.applthermaleng.2017.03.125

Cited by 27 publications

(7 citation statements)

References 32 publications

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“…Single stage axial, dual stage axial and single stage radial turbine were investigated in the study to compare performance and output power. The results showed that dual stage axial turbine had better performance at off design conditions while single stage radial turbine generated higher power (approximately 1.7 times greater than dual stage turbine at high pressures) at the same condition . In addition, CFD analysis was applied in studies to optimize radial turbine for solar Brayton cycles.…”

Section: Brayton Cyclesmentioning

confidence: 99%

“…The results showed that dual stage axial turbine had better performance at off design conditions while single stage radial turbine generated higher power (approximately 1.7 times greater than dual stage turbine at high pressures) at the same condition. 69 In addition, CFD analysis was applied in studies to optimize radial turbine for solar Brayton cycles. Since turbine efficiency improvement leads to increase in cycle thermal efficiency (for instance, 10% increase in turbine efficiency can improve overall cycle efficiency up to 6% 70 ), Daabo et al 71 used CFD tool and one dimensional mean line approach in optimizing radial turbine for solar Brayton cycle.…”

Section: Brayton Cyclesmentioning

confidence: 99%

“…Numerical simulation has been conducted on different components of cycle such as compressor, turbine, and heat receiver . Daabo et al applied computational fluid dynamic (CFD) analysis in solar Brayton cycle. Single stage axial, dual stage axial and single stage radial turbine were investigated in the study to compare performance and output power.…”

Section: Brayton Cyclesmentioning

confidence: 99%

See 2 more Smart Citations

A review on solar‐assisted gas turbines

Ahmadi

Nazari

Ghasempour

et al. 2018

Energy Science & Engineering

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The thermal energy of the sun can be used for electricity generation. Solar thermal energy can be applied with fossil fuels or independently in order to reduce the cost of generated electricity and CO2 emission. Several cycles are introduced to extract solar thermal energy to be used in power plants. Brayton cycles, Rankine‐Brayton cycles, and supercritical Brayton cycles are among the most conventional ones. Based on the reviewed researches, using solar energy in addition to fossil fuels results in lower carbon dioxide emission and lower levelized cost of the generated electricity. Moreover, thermodynamic and economic analyses of the cycles revealed that heat recovery leads to higher efficiency while increase capital cost. The efficiency of solar‐assisted gas turbines depend on various parameters including pressure ratio, turbine inlet temperature, heat absorber geometry and the performance of the components. The enhancement in the efficiency of the cycles by applying each method depends on the configuration, operating condition. For instance, results have shown that 10% increase in turbine efficiency can led to 6%‐12% improvement in the efficiency of a closed‐Brayton cycle.

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Section: Brayton Cyclesmentioning

confidence: 99%

Section: Brayton Cyclesmentioning

confidence: 99%

Section: Brayton Cyclesmentioning

confidence: 99%

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A review on solar‐assisted gas turbines

Ahmadi

Nazari

Ghasempour

et al. 2018

Energy Science & Engineering

View full text Add to dashboard Cite

show abstract

“…Their 1D results correlated well with the CFD results. Daabo et al [42] presented two design models for axial and radial turbines to be used in solar powered Brayton cycles. Their CFD analyses were validated against experimental work and then used to validate the mean-line models.…”

Section: Introductionmentioning

confidence: 99%

Generation of 3D Turbine Blades for Automotive Organic Rankine Cycles: Mathematical and Computational Perspectives

2020

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Organic Rankine cycle technology is gaining increasing interest as one of potent future waste heat recovery potential from internal combustion engines. The turbine is the component where power production takes place. Therefore, careful attention to the turbine design through mathematical and numerical simulations is required. As the rotor is the main component of the turbine, the generation of the 3D shape of the rotor blades and stator vanes is of great importance. Although several types of commercial software have been developed, such types are still expensive and time-consuming. In this study, detailed mathematical modelling was presented. To account for real gas properties, REFPROP software was used. Moreover, a detailed 3D CFD numerical analysis was presented to examine the nature of the flow after generating the 3D shapes of the turbine. Moreover, finite element analysis was performed using various types of materials to obtain best-fit material for the current application. As the turbine is part of a larger system (i.e., ORC system), the effects of its performance on the whole ORC system were discussed. The results showed that the flow was smooth with no recirculation at the design point except at the last part of the suction surface where strong vortices were noticed. Despite the strong vortices, the mathematical model proved to be an effective and fast tool for the generation of the 3D shapes of turbine blades and vanes. The deviations between the 1D mean-line and 3D CFD in turbine efficiency and power output were 2.28% and 5.10%, respectively.

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“…In general, Brayton cycles are studied to improve the energy recovered from solar power plants. It is possible to find numerous studies about the cycle layout design for closed Brayton cycles working with CO2 in solar plants can be found [19] [20] [21], the interest of regenerative and inverse Brayton cycles [22] [23] and the turbine design for the Brayton cycle of these solar plants [24]. In addition, WHR using Brayton cycles in IC engines for industrial applications, where space requirements and dynamic conditions are less restrictive, has been studied [25].…”

Section: Introductionmentioning

confidence: 99%

Further analysis of a compression-expansion machine for a Brayton Waste Heat Recovery cycle on an IC engine

Galindo

Guardiola

Dolz

et al. 2018

Applied Thermal Engineering

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In order to comply with the legislation, car manufacturers are looking for a way to lower the CO2 emission by improving engine efficiency. About one third of the fuel combustion energy is wasted through exhaust gasses. Waste Heat Recovery (WHR) could improve engine efficiency by recovering a part of exhaust gasses energy. In this study, the potential use of an open loop Brayton cycle with a volumetric compression expansion machine for exhaust gas waste heat recovery was investigated. The use of the Brayton cycle system with only two main elements, a heat exchanger and a volumetric machine, could be very interesting due to its compactness and versatility. However, the publications on this subject are scarce. The present paper aims at bridging this knowledge gap by studying the cycle viability for passenger car application characterized by low temperatures, variable working conditions and several restrictions of available space and weight. The simulated vehicle was a Ford Mondeo family car with an Ecoboost 2.0 engine. The main components of the Brayton cycle WHR system model were a heat exchanger and an alternating piston machine that was used both as a compressor and as an expander. Theoretical studies were conducted in the compression-expansion machine model in order to determine the main parameters that influence the cycle and optimise those parameters in order to obtain the maximum recuperated power. The conclusion was that the cycle viability is not clear because cycle losses are in the same order of magnitude as the recuperated power. Considering future improvements of the compressionexpansion machine and the heat exchanger, the recuperated power could be positive. Nevertheless, it is hard to expect that recuperated power would be sufficient to justify the application of this WHR system in the vehicle.

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Numerical analysis of small scale axial and radial turbines for solar powered Brayton cycle application

Cited by 27 publications

References 32 publications

A review on solar‐assisted gas turbines

A review on solar‐assisted gas turbines

Generation of 3D Turbine Blades for Automotive Organic Rankine Cycles: Mathematical and Computational Perspectives

Further analysis of a compression-expansion machine for a Brayton Waste Heat Recovery cycle on an IC engine

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