Computational fluid dynamics simulation and optimization of the fluid flow behaviour in a multi‐stage solar updraft tower using a new chimney design-Reference-Cited by-同舟云学术

Computational fluid dynamics simulation and optimization of the fluid flow behaviour in a multi‐stage solar updraft tower using a new chimney design

Published:2023-06-30 Issue:1 Volume:102 Page:506-517
ISSN:0008-4034
Container-title:The Canadian Journal of Chemical Engineering
language:en
Short-container-title:Can J Chem Eng

Author:

Ghriss Ons¹,Aryanfar Yashar²^ORCID,Bouabidi Abdallah³,Driss Zied⁴,García Alcaraz Jorge Luis⁵

Affiliation:

1. National Engineering School of Gabes (ENIG), Research Laboratory ‘Processes, Energetics Environment and Electrical Systems’ Gabes University Gabes Tunisia

2. Department of Electric Engineering and Computation Autonomous University of Ciudad Juárez Chihuahua Mexico

3. Unit of Mechanical Modeling, Energy & Materials (M2EM), UR17ES47, National School of Engineers of Gabes (ENIG) Gabes University Gabes Tunisia

4. Laboratory of Electro‐Mechanic Systems (LASEM), National Engineering School of Sfax (ENIS) University of Sfax (US) Sfax Tunisia

5. Department of Industrial Engineering and Manufacturing Autonomous University of Ciudad Juárez Chihuahua Mexico

Abstract

AbstractThis work proposes a new chimney design that allows for the development of a multi‐stage solar updraft tower (SUT). The new design consists of two successive divergent chimneys. A 3D model was established to inspect the air flow behaviour within the SUT in six configurations: four multi‐stage systems with four divergence angles of the second stage were compared to the simple conventional SUT and the simple SUT with a divergent chimney. The new SUT performs better than the conventional one, while the two‐stage solar tower multiplied the system efficiency. Two high‐velocity zones appeared for the two‐stage SUT, whereas one zone occurred for the conventional system. The velocity in the two zones achieved a significant value, like that of the conventional system. In addition, the second stage's divergence angle directly impacts the velocity value inside the two stages. The static pressure distribution varies with the change in chimney design. The depression area occurs twice for the multi‐stage SUT in the inlet of each stage.

Publisher

Wiley

Subject

General Chemical Engineering

Link

https://onlinelibrary.wiley.com/doi/pdf/10.1002/cjce.25031

Reference42 articles.

1. Modeling and analysis of a two-stage ORC for recovering waste heat of single flash geothermal cycle

2. Thermo-economic analysis of working fluids for a ground source heat pump for domestic uses

3. Energy and exergy and economic (3E) analysis of a two-stage organic Rankine cycle for single flash geothermal power plant exhaust exergy recovery

4. Developing a wind power forecasting system based on deep learning with attention mechanism

5. Energy, exergy and economic analysis of combined solar ORC-VCC power plant

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