Techno-economic assessment of evacuated flat-plate solar collector system for industrial process heat

Hassan, Z; Mahmood, M; Ahmed, N; Saeed, MH; Khan, R; Abbas, MM; Kalam, MA; Almomani, F; Abdelsalam, E

Techno-economic assessment of evacuated flat-plate solar collector system for industrial process heat

Hassan, Z Mahmood, M Ahmed, N Saeed, MH Khan, R Abbas, MM Kalam, MA Almomani, F Abdelsalam, E

Permalink

Publisher:: Wiley
Publication Type:: Journal Article
Citation:: Energy Science and Engineering, 2023, 11, (6), pp. 2185-2201
Issue Date:: 2023-06-01

Open Access

Copyright Clearance Process

Recently Added
In Progress
Open Access

This item is open access.

Adobe PDF

Download Published versionAdobe PDF (4.65 MB)

View on publisher's site

View statistics

Full metadata record

Field	Value	Language
dc.contributor.author	Hassan, Z
dc.contributor.author	Mahmood, M
dc.contributor.author	Ahmed, N
dc.contributor.author	Saeed, MH
dc.contributor.author	Khan, R
dc.contributor.author	Abbas, MM
dc.contributor.author	Kalam, MA
dc.contributor.author	Almomani, F
dc.contributor.author	Abdelsalam, E
dc.date.accessioned	2024-04-12T01:23:45Z
dc.date.available	2024-04-12T01:23:45Z
dc.date.issued	2023-06-01
dc.identifier.citation	Energy Science and Engineering, 2023, 11, (6), pp. 2185-2201
dc.identifier.issn	2050-0505
dc.identifier.issn	2050-0505
dc.identifier.uri	http://hdl.handle.net/10453/177797
dc.description.abstract	In the industrial sector, hot water applications constitute a significant share of final energy consumption. This creates a wide demand-supply energy gap that must be bridged by integrating renewable sources with conventional fuels. This paper presents the performance analysis of a solar water heating system based on an evacuated flat-plate collector (EFPC) with a surface area of 4 m2. A water–glycol mixture was used as the heat transfer fluid (HTF) with mass flow rates of 0.03, 0.0336, and 0.0504 kg/s under a vacuum pressure of –0.8 bar created inside the collector. A detailed numerical model was developed in MATLAB for the proposed EFPC system, followed by experimental validation. A maximum root mean square error of 2.81 for the absorber temperature and a percentage error of 6.62 was observed for the thermal efficiency in model validation. This substantiates the model's capability to predict actual system performance with reasonable accuracy. The maximum thermal efficiency of the EFPC is 78% with a maximum fluid outlet temperature of 98°C in June and 69°C in January. The maximum useful energy extracted is 1300 W in January. Additionally, the effect of design parameters on system performance such as mass flow rates, collector areas, tube spacing, and different HTF mixtures is simulated. Lastly, an economic analysis of the EFPC was conducted for hot water demand in a textile industry. The results revealed a payback period of 7.4 years, which highlights the feasibility of this system.
dc.language	en
dc.publisher	Wiley
dc.relation.ispartof	Energy Science and Engineering
dc.relation.isbasedon	10.1002/ese3.1447
dc.rights	info:eu-repo/semantics/openAccess
dc.subject.classification	4008 Electrical engineering
dc.subject.classification	4011 Environmental engineering
dc.subject.classification	4017 Mechanical engineering
dc.title	Techno-economic assessment of evacuated flat-plate solar collector system for industrial process heat
dc.type	Journal Article
utslib.citation.volume	11
pubs.organisational-group	University of Technology Sydney
pubs.organisational-group	University of Technology Sydney/Faculty of Engineering and Information Technology
pubs.organisational-group	University of Technology Sydney/Faculty of Engineering and Information Technology/School of Civil and Environmental Engineering
pubs.organisational-group	University of Technology Sydney/Strength - CTWW - Centre for Technology in Water and Wastewater Treatment
utslib.copyright.status	open_access	*
dc.date.updated	2024-04-12T01:23:43Z
pubs.issue	6
pubs.publication-status	Published
pubs.volume	11
utslib.citation.issue	6

Abstract:

In the industrial sector, hot water applications constitute a significant share of final energy consumption. This creates a wide demand-supply energy gap that must be bridged by integrating renewable sources with conventional fuels. This paper presents the performance analysis of a solar water heating system based on an evacuated flat-plate collector (EFPC) with a surface area of 4 m2. A water–glycol mixture was used as the heat transfer fluid (HTF) with mass flow rates of 0.03, 0.0336, and 0.0504 kg/s under a vacuum pressure of –0.8 bar created inside the collector. A detailed numerical model was developed in MATLAB for the proposed EFPC system, followed by experimental validation. A maximum root mean square error of 2.81 for the absorber temperature and a percentage error of 6.62 was observed for the thermal efficiency in model validation. This substantiates the model's capability to predict actual system performance with reasonable accuracy. The maximum thermal efficiency of the EFPC is 78% with a maximum fluid outlet temperature of 98°C in June and 69°C in January. The maximum useful energy extracted is 1300 W in January. Additionally, the effect of design parameters on system performance such as mass flow rates, collector areas, tube spacing, and different HTF mixtures is simulated. Lastly, an economic analysis of the EFPC was conducted for hot water demand in a textile industry. The results revealed a payback period of 7.4 years, which highlights the feasibility of this system.

Please use this identifier to cite or link to this item:

http://hdl.handle.net/10453/177797