Development and Validation of a Thermo-Economic Model for Design Optimisation and Off-Design Performance Evaluation of a Pure Solar Microturbine

Iaria, Davide; Nipkey, H.; Al-Zaili, Jafar; Sayma, A. I.; Assadi, Mohsen

doi:10.3390/en11113199

Cited by 5 publications

(2 citation statements)

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“…m is the mass flow rate; C P, f and C S are the specific heats of the fluid and solid, respectively; ρ S is the storage media density; and ∆t is the target charging/discharging time. The overall volume of the system can be calculated using Equation (24).…”

Section: Case Studymentioning

confidence: 99%

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Development of a Model for Performance Analysis of a Honeycomb Thermal Energy Storage for Solar Power Microturbine Applications

et al. 2019

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Solar power microturbines are required to produce steady power despite the fluctuating solar radiation, with concerns on the dispatchability of such plants where thermal energy storage may offer a solution to address the issue. This paper presents a mathematical model for performance prediction of a honeycomb sensible-heat thermal energy storage designed for application of concentrated solar power microturbine. The focus in the model is to consider the laminar developing boundary layers at the entry of the flow channels, which could have a profound effect on the heat-transfer coefficient due to large velocity and temperature gradients, an effect which has not been considered in the modelling of such storage systems. Analysing the thermal and hydrodynamic boundary layer development, the Nusselt number and the friction factor were evaluated using a validated conjugate heat-transfer method. The simulations results were used to develop accurate regression functions for Nusselt number and friction factor. These formulations have been adopted within a one-dimensional model to evaluate the performance of the storage under different operating conditions. The model was in good agreement with conjugate heat transfer results with maximum relative error below 2%. Two case studies are presented to demonstrate the applicability of the proposed methodology.

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Section: Case Studymentioning

confidence: 99%

“…The daily variation of the solar irradiation is such that a second charging phase can be included during the day. The details of the cycle calculation and optimisation are given in References [22][23][24]. During the first discharging phase, the plant is operated to maintain the power output constant to the value 8 kWe.…”

Section: Case Studymentioning

confidence: 99%