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Natural and forced convection simulations of a concentrating solar power receiver

Applied Computational Fluid Dynamics

Title: Natural and forced convection simulations of a concentrating solar power receiver

Scientific Essay , 2016 , 44 Pages , Grade: A

Autor:in: Simon Homes (Author), Martin Rakowitsch (Author), Maximilian Scheid (Author)

Engineering - Mechanical Engineering

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Summary Details

Concentrating Solar Power Receiver (CSPs) collect solar radiation with large mirrors and reflect them concentrated on a receiver. Here, a Dish-Stirling type thermal cycle is driven. One of the key preconditions for a cost competitive production of power is a good efficiency factor.

Within the framework of this project, we want to examine and qualitatively quantify the heat losses of a Dish Sterling Concentrating Solar Power Receiver. It is the aim to determine the individual driving forces for heat losses by analysing natural convection on the one hand and two different setups of forced convection on the other hand.

In section 2, we present the abstract model of a solar receiver. Then, we will discuss the necessary models to simulate turbulent flow and heat transfer of air and justify our choice of numerical methods to solve the governing equations in ANSYS Fluent. Furthermore, we will introduce performance factors to monitor the heat losses of the solar receiver.

Coherent with the two main physical phenomena of heat losses, we subdivided the report in normal convection (NC, section 3) and forced convection (FC, section 4), where we outline the specific model characteristics, boundary conditions, grid requirements and benchmarks respectively. A profound analysis of the results and an outlook on further research in section 5 finalise the report.

Details

Title
Natural and forced convection simulations of a concentrating solar power receiver
Subtitle
Applied Computational Fluid Dynamics
College
KTH Royal Institute of Technology  (School of Engineering Sciences)
Course
Applied Computational Fluid Dynamics
Grade
A
Authors
Simon Homes (Author), Martin Rakowitsch (Author), Maximilian Scheid (Author)
Publication Year
2016
Pages
44
Catalog Number
V342045
ISBN (eBook)
9783668334373
ISBN (Book)
9783668334380
Language
English
Tags
CFD ANSYS KTH Convection Forced Natural Solar Receiver Fluent Navier Stokes Computational Fluid Dynamics
Product Safety
GRIN Publishing GmbH
Quote paper
Simon Homes (Author), Martin Rakowitsch (Author), Maximilian Scheid (Author), 2016, Natural and forced convection simulations of a concentrating solar power receiver, Munich, GRIN Verlag, https://www.hausarbeiten.de/document/342045
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Excerpt from  44  pages
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