Monte Carlo advances and concentrated solar applications

Delatorre, J.; Baud, Germain; Bézian, Jean-Jacques; Blanco, Stéphane; Caliot, Cyril; Cornet, J. F.; Coustet, Christophe; Dauchet, Jérémi; Hafi, Mouna El; Eymet, Vincent; Fournier, Richard; Gautrais, Jacques; Gourmel, O.; Joseph, David; Meilhac, N.; Pajot, Anthony; Paulin, Mathias; Perez, P.; Piaud, Benjamin; Roger, Maxime; Rolland, Julien Yves; Veynandt, François; Weitz, Sébastian

doi:10.1016/j.solener.2013.02.035

Cited by 83 publications

(89 citation statements)

References 29 publications

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“…This Monte Carlo algorithm, previously presented as the MCST 1 algorithm (Farges et al, 2015), takes advantage of Monte Carlo integral formulation as outlined by de La Torre et al (2014). An overview of the specific Monte Carlo algorithm, dealing with the sun's positions in the sky, is presented in fig.…”

Section: Mcst Monte Carlo Algorithmmentioning

confidence: 99%

“…Some dates are sampled using an importance sampling approach, then locations on the heliostat field where the sun rays are first reflected are uniformly sampled, after which the algorithm follows the behaviour of the rays in the SPT, ie computes reflections until each ray hits the final receiver or is lost. The MCST algorithm is thoroughly explained in (de La Torre et al, 2014), so it was decided not to go into detail here but only to reintroduce this algorithm with the addition of the yearly heliostat field optical efficiency estimation:…”

Section: Mcst Monte Carlo Algorithmmentioning

confidence: 99%

“…The direct model is implemented in the numerical framework EDStaR (de La Torre et al, 2014). This tool yields the practical implementation of a Monte Carlo algorithm for the radiative heat transfer model, making use of an integral formulation, and takes into consideration zero-variance approaches and sensitivity estimation as presented by Hoogenboom (2008) and Roger et al (2005).…”

Section: A Specific Computing Frameworkmentioning

confidence: 99%

“…It benefits from all the modern possibilities of computing such as massive parallelization and acceleration of ray tracing in a complex geometry. Different solar applications have already been simulated with this tool (de La Torre et al, 2014). EDStaR permits very efficient implementation of the direct model.…”

Section: A Specific Computing Frameworkmentioning

confidence: 99%

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Global optimization of solar power tower systems using a Monte Carlo algorithm: Application to a redesign of the PS10 solar thermal power plant

2018

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There is a need to enhance the performance of Solar Power Tower (SPT) systems in view of their significant capital costs. In this context, the preliminary design step is of great interest as improvements here can reduce the global cost. This paper presents an optimization method that approaches optimal SPT system design through the coupling of a Particle Swarm Optimization algorithm and a Monte Carlo algorithm, in order to assess both the yearly heliostat field optical efficiency and the thermal energy collected annually by an SPT system. This global optimization approach is then validated on a wellknown SPT system, ie the PS10 Solar Thermal Power plant. First, the direct model is compared to in-situ measurements and simulation results. Then, the PS10 heliostat field is redesigned using the optimization tool. This redesign step leads to an annual gain between 3.34 % and 23.5 % in terms of the thermal energy collected and up to about 9 % in terms of the heliostat field optical efficiency from case to case.

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Section: Mcst Monte Carlo Algorithmmentioning

confidence: 99%

Section: Mcst Monte Carlo Algorithmmentioning

confidence: 99%

Section: A Specific Computing Frameworkmentioning

confidence: 99%

Section: A Specific Computing Frameworkmentioning

confidence: 99%

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Global optimization of solar power tower systems using a Monte Carlo algorithm: Application to a redesign of the PS10 solar thermal power plant

2018

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“…Differences among the existing Monte Carlo ray tracing simulation packages include the programming language, the use of parallelization, the available surface geometries, light source (including sunshape) models, surface error and optical property models, the user interface, the post-processing capabilities, and the level of technical support. The field is dynamic, and recent advances in Monte Carlo ray tracing modeling are being presently evaluated for solar concentrated power applications (Delatorre et al, 2014).…”

Section: Monte Carlo Ray Tracing Codesmentioning

confidence: 99%

High-flux optical systems for solar thermochemistry

et al. 2017

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a b s t r a c tHigh-flux optical systems (HFOSs) are optical concentrators used to increase the radiative flux of the natural terrestrial solar irradiation. High radiative flux concentration leads to high energy density in solar receivers which allows to obtain high temperatures. In solar thermochemical applications, the hightemperature heat drives endothermic thermochemical reactions. HFOSs have been deployed for research and development of solar thermochemical devices and systems, from solar reacting media to solar reactors. Here, we review the designs and characteristics of HFOSs as well as challenges and opportunities in the area of high-flux optical systems for solar thermochemical applications.

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Continuous flow photocatalytic reactor using TiO₂‐coated foams, modeling and experimental operating mode

et al. 2022

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This article aims to build a modeling and simulating tool of the operation of a continuous flow heterogeneous photocatalysis reactor. Continuous flow is well-known in reactor engineering for allowing advanced control of reactor and scaling-up with great confidence, but little research has addressed it's potential for this kind of application. In developing this model, particular attention was paid to the coupling which occurs at local scale between the radiative transfer and the reaction kinetics of advanced oxidation of a target organic micro-pollutant. The solution of the radiative transfer equation by Monte Carlo method was applied to a photocatalyst supported on a macroporous ceramic foam forming an efficient 3D support. After identification of the kinetic law of degradation, the dynamic simulation model was validated through comparison with a series of experiments performed for different but constant irradiations and for variable irradiations approaching, in term of intensity and dynamics, natural solar radiation.

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Monte Carlo advances and concentrated solar applications

Cited by 83 publications

References 29 publications

Global optimization of solar power tower systems using a Monte Carlo algorithm: Application to a redesign of the PS10 solar thermal power plant

Global optimization of solar power tower systems using a Monte Carlo algorithm: Application to a redesign of the PS10 solar thermal power plant

High-flux optical systems for solar thermochemistry

Continuous flow photocatalytic reactor using TiO₂‐coated foams, modeling and experimental operating mode

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Monte Carlo advances and concentrated solar applications

Cited by 83 publications

References 29 publications

Global optimization of solar power tower systems using a Monte Carlo algorithm: Application to a redesign of the PS10 solar thermal power plant

Global optimization of solar power tower systems using a Monte Carlo algorithm: Application to a redesign of the PS10 solar thermal power plant

High-flux optical systems for solar thermochemistry

Continuous flow photocatalytic reactor using TiO2‐coated foams, modeling and experimental operating mode

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Product

Resources

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Continuous flow photocatalytic reactor using TiO₂‐coated foams, modeling and experimental operating mode