Helically coiled cavity receiver for a micro-scale direct generation steam Rankine cycle using a novel solar dish design

Sub-Saharan Africa has an underutilised solar resource that is available to provide distributed-scale power to rural communities that are not reached by the current grid systems that are in place. Renewable power generation systems are typically infeasible for this purpose due to their high manufact...

Full description

Bibliographic Details
Main Author: Swanepoel, Jonathan Kyle
Other Authors: Le Roux, Willem G.
Language:en
Published: University of Pretoria 2020
Subjects:
Online Access:http://hdl.handle.net/2263/73460
Swanepoel, JK 2019, Helically coiled cavity receiver for a micro-scale direct generation steam Rankine cycle using a novel solar dish design, MEng (Mechanical) Dissertation, University of Pretoria, Pretoria, viewed yymmdd <http://hdl.handle.net/2263/73460>
id ndltd-netd.ac.za-oai-union.ndltd.org-up-oai-repository.up.ac.za-2263-73460
record_format oai_dc
collection NDLTD
language en
sources NDLTD
topic UCTD
Micro-scale
Steam
Rankine cylce
Lunar flux mapping
Experimental analysis
spellingShingle UCTD
Micro-scale
Steam
Rankine cylce
Lunar flux mapping
Experimental analysis
Swanepoel, Jonathan Kyle
Helically coiled cavity receiver for a micro-scale direct generation steam Rankine cycle using a novel solar dish design
description Sub-Saharan Africa has an underutilised solar resource that is available to provide distributed-scale power to rural communities that are not reached by the current grid systems that are in place. Renewable power generation systems are typically infeasible for this purpose due to their high manufacturing and maintenance costs. This research proposes to address this by experimentally investigating the performance of a micro-scale, solar thermal Rankine cycle with direct steam generation using an affordable solar collector design. The intended power generation range is between 0.1 and 1 kW, which can be used for the direct mechanical pumping of rural irrigation systems or municipal water supplies. The study focuses on the performance of the solar collector (the solar reflector and the solar receiver) under realistic solar thermal conditions in sub-Saharan Africa, as it is considered to be one of the most important components in the solar thermal Rankine cycle. The performance of the solar collector was first characterised in an optical analysis of the new faceted dish reflector design, which comprised six Mylar membranes stretched over the elliptical rims of television satellite dishes. The optical analysis was conducted with the main goal of determining how much concentrated solar radiation would intercept the experimental receiver aperture during solar testing. This was determined by measuring the reflectivity of the reflector facets through ultraviolet and visible light (UV-VIS) spectroscopy and producing an intercept factor trend as a function of receiver aperture size through photographic lunar flux mapping. Based on the spectroscopy analysis, the spectral reflectivity of the clean Mylar facets was determined to be 97% for the visible light spectrum. The intercept factor was determined to be 87% for the designed receiver aperture diameter of 135 mm. The thermal testing took place on a clear, sunny day with low wind velocities. The solar collector followed the arc of the sun throughout the day with a 1° tracking error. During the testing, municipal water was passed through the receiver at 0.284 g/s and the temperature and pressure within the receiver were recorded. A 91-minute testing period occurred, where the inlet and outlet process flows obtained relatively constant operating temperatures with the inlet temperature at 54 °C and the outlet temperature at 343 °C. The total solar irradiance dropped from 801 to 705 W/m2 during this testing period. Using a reflector with a total incident area of 2.73 m2, the total radiation intercepted at the aperture dropped from 1 845 to 1 625 W during this period. The total power capture by the working fluid averaged at approximately 861 W and the total rate of heat loss was determined to be between 1 000 and 750 W. An average collector efficiency of 42% and an average receiver efficiency of 49% were determined for the testing period. An analysis of the heat loss showed that approximately 84% of the heat was lost through the aperture, of which, 31% was from reflected radiation. The second-law analysis showed that most of the irreversibility in the solar collector was caused by absorption of the concentrated radiation at the coil surface. This was because of the large temperature difference between the sun and the receiver coils. The experimental thermal analysis highlighted the design challenges of the micro-scale thermal Rankine cycle. However, the analysis showed that a solar collector can be constructed using locally sourced, affordable materials and can be used to produce power at a micro-scale. With appropriate attention given to optimising the collector design and determining the optimum operating conditions of the solar receiver, the power cycle would be able to compete with current technologies to provide decentralised power to communities in need. === Dissertation (MEng)--University of Pretoria, 2019. === Technology Innovation Agency (TIA); National Research Foundation (NRF); Department of Science and Innovation (DSI) === Mechanical and Aeronautical Engineering === MEng (Mechanical) === Unrestricted
author2 Le Roux, Willem G.
author_facet Le Roux, Willem G.
Swanepoel, Jonathan Kyle
author Swanepoel, Jonathan Kyle
author_sort Swanepoel, Jonathan Kyle
title Helically coiled cavity receiver for a micro-scale direct generation steam Rankine cycle using a novel solar dish design
title_short Helically coiled cavity receiver for a micro-scale direct generation steam Rankine cycle using a novel solar dish design
title_full Helically coiled cavity receiver for a micro-scale direct generation steam Rankine cycle using a novel solar dish design
title_fullStr Helically coiled cavity receiver for a micro-scale direct generation steam Rankine cycle using a novel solar dish design
title_full_unstemmed Helically coiled cavity receiver for a micro-scale direct generation steam Rankine cycle using a novel solar dish design
title_sort helically coiled cavity receiver for a micro-scale direct generation steam rankine cycle using a novel solar dish design
publisher University of Pretoria
publishDate 2020
url http://hdl.handle.net/2263/73460
Swanepoel, JK 2019, Helically coiled cavity receiver for a micro-scale direct generation steam Rankine cycle using a novel solar dish design, MEng (Mechanical) Dissertation, University of Pretoria, Pretoria, viewed yymmdd <http://hdl.handle.net/2263/73460>
work_keys_str_mv AT swanepoeljonathankyle helicallycoiledcavityreceiverforamicroscaledirectgenerationsteamrankinecycleusinganovelsolardishdesign
_version_ 1719384377836699648
spelling ndltd-netd.ac.za-oai-union.ndltd.org-up-oai-repository.up.ac.za-2263-734602021-03-25T05:11:05Z Helically coiled cavity receiver for a micro-scale direct generation steam Rankine cycle using a novel solar dish design Swanepoel, Jonathan Kyle Le Roux, Willem G. Lexmond, Axel S. jon.swanie@gmail.com Meyer, Josua P. UCTD Micro-scale Steam Rankine cylce Lunar flux mapping Experimental analysis Sub-Saharan Africa has an underutilised solar resource that is available to provide distributed-scale power to rural communities that are not reached by the current grid systems that are in place. Renewable power generation systems are typically infeasible for this purpose due to their high manufacturing and maintenance costs. This research proposes to address this by experimentally investigating the performance of a micro-scale, solar thermal Rankine cycle with direct steam generation using an affordable solar collector design. The intended power generation range is between 0.1 and 1 kW, which can be used for the direct mechanical pumping of rural irrigation systems or municipal water supplies. The study focuses on the performance of the solar collector (the solar reflector and the solar receiver) under realistic solar thermal conditions in sub-Saharan Africa, as it is considered to be one of the most important components in the solar thermal Rankine cycle. The performance of the solar collector was first characterised in an optical analysis of the new faceted dish reflector design, which comprised six Mylar membranes stretched over the elliptical rims of television satellite dishes. The optical analysis was conducted with the main goal of determining how much concentrated solar radiation would intercept the experimental receiver aperture during solar testing. This was determined by measuring the reflectivity of the reflector facets through ultraviolet and visible light (UV-VIS) spectroscopy and producing an intercept factor trend as a function of receiver aperture size through photographic lunar flux mapping. Based on the spectroscopy analysis, the spectral reflectivity of the clean Mylar facets was determined to be 97% for the visible light spectrum. The intercept factor was determined to be 87% for the designed receiver aperture diameter of 135 mm. The thermal testing took place on a clear, sunny day with low wind velocities. The solar collector followed the arc of the sun throughout the day with a 1° tracking error. During the testing, municipal water was passed through the receiver at 0.284 g/s and the temperature and pressure within the receiver were recorded. A 91-minute testing period occurred, where the inlet and outlet process flows obtained relatively constant operating temperatures with the inlet temperature at 54 °C and the outlet temperature at 343 °C. The total solar irradiance dropped from 801 to 705 W/m2 during this testing period. Using a reflector with a total incident area of 2.73 m2, the total radiation intercepted at the aperture dropped from 1 845 to 1 625 W during this period. The total power capture by the working fluid averaged at approximately 861 W and the total rate of heat loss was determined to be between 1 000 and 750 W. An average collector efficiency of 42% and an average receiver efficiency of 49% were determined for the testing period. An analysis of the heat loss showed that approximately 84% of the heat was lost through the aperture, of which, 31% was from reflected radiation. The second-law analysis showed that most of the irreversibility in the solar collector was caused by absorption of the concentrated radiation at the coil surface. This was because of the large temperature difference between the sun and the receiver coils. The experimental thermal analysis highlighted the design challenges of the micro-scale thermal Rankine cycle. However, the analysis showed that a solar collector can be constructed using locally sourced, affordable materials and can be used to produce power at a micro-scale. With appropriate attention given to optimising the collector design and determining the optimum operating conditions of the solar receiver, the power cycle would be able to compete with current technologies to provide decentralised power to communities in need. Dissertation (MEng)--University of Pretoria, 2019. Technology Innovation Agency (TIA); National Research Foundation (NRF); Department of Science and Innovation (DSI) Mechanical and Aeronautical Engineering MEng (Mechanical) Unrestricted 2020-02-21T07:20:38Z 2020-02-21T07:20:38Z 2020-04-14 2019 Dissertation http://hdl.handle.net/2263/73460 Swanepoel, JK 2019, Helically coiled cavity receiver for a micro-scale direct generation steam Rankine cycle using a novel solar dish design, MEng (Mechanical) Dissertation, University of Pretoria, Pretoria, viewed yymmdd <http://hdl.handle.net/2263/73460> A2020 en © 2019 University of Pretoria. All rights reserved. The copyright in this work vests in the University of Pretoria. No part of this work may be reproduced or transmitted in any form or by any means, without the prior written permission of the University of Pretoria. University of Pretoria