Multi-Objective Optimization of Hybrid Renewable Tri-Generation System Performance for Buildings

Ghorab, Mohamed; Yang, Libing; Entchev, Evgueniy; Lee, Euy-Joon; Kang, Eun-Chul; Kim, Yu-Jin; Bae, Sangmu; Nam, Yujin; Kim, Kwonye

doi:10.3390/app12020888

Cited by 8 publications

(1 citation statement)

References 52 publications

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“…The system's optimization improves net power, cooling, TGOR, and energy efficiency by 2.58, 22.69, 14.04, and 13.26%. Ghorab et al [26] improved a household hybrid renewable energy system's annual energy performance. The multi-module hybrid system includes a ground-air heat exchanger, photovoltaic thermal panels, and an air-to-water heat pump (AWHP).…”

Section: Tri-generation/poly-generation Systems Integrated With Orcmentioning

confidence: 99%

Energy Performance Assessment of a Novel Solar Poly-Generation System Using Various ORC Working Fluids in Residential Buildings

et al. 2022

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Poly-generation systems are an exciting new technology that provide an alternative to separating existing energy production methods in buildings. A poly-generation system enables the efficient simultaneous production of heating, cooling, fresh water, and electricity, resulting in many technological, economic, energy recovery, and environmental advantages. This study numerically investigates three proposed novel solar-driven poly-generation systems (BS, IS-I, and IS-II) integrated with organic Rankine cycle (ORC), humidification-dehumidification desalination system (HDH), and desiccant cooling system (DCS) with different heat recovery system arrangements. The suggested systems supply residential structures with energy, space conditioning, domestic heating, and fresh water. The effects of system operating circumstances on productivity and performance characteristics and several organic working fluid types (n-octane, R245fa, R113, isopentane, and toluene) on optimum system performance have been investigated. The results show that (i) the average enhancement percentage of TGOR using integrated poly-generation systems over the separated ones is 68.5%, 68.5%, and 95.5% for BS, IS-I, and IS-II systems, respectively; (ii) when comparing the three systems, the IS-I system outperforms the other systems (BS & IS-II); and (iii) the maximum values of W•net, m•fresh, Q•cooling, and Q•heating, obtained for different proposed systems using n-octane are 102 kW (all systems), 214.7 kg/h (IS-II), 29.94 kW (IS-II), and 225.6 kW (IS-I); (iv) R113 has the highest TGOR of 0.6924 (IS-I) compared to other organic fluids. (v) The improvements in W•net, m•fresh, Q•cooling, and Q•heating with using toluene instead of R113 at tf1 = 40 °C are 177.5%, 105.8%, 389.25%, and 79%, respectively.

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Section: Tri-generation/poly-generation Systems Integrated With Orcmentioning

confidence: 99%

Energy Performance Assessment of a Novel Solar Poly-Generation System Using Various ORC Working Fluids in Residential Buildings

et al. 2022

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Energy analysis of a novel solar tri-generation system using different ORC working fluids

Almohammadi

Al‐Zahrani

Refaey

et al. 2023

Case Studies in Thermal Engineering

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4E analysis and tri-objective optimization of a novel solar 4th cogeneration system for a smart residential building in various climates of Iran

Saadmohammadi,

Sajadi

2024

Energy Conversion and Management

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Multi-Objective Optimization of Hybrid Renewable Tri-Generation System Performance for Buildings

Cited by 8 publications

References 52 publications

Energy Performance Assessment of a Novel Solar Poly-Generation System Using Various ORC Working Fluids in Residential Buildings

Energy Performance Assessment of a Novel Solar Poly-Generation System Using Various ORC Working Fluids in Residential Buildings

Energy analysis of a novel solar tri-generation system using different ORC working fluids

4E analysis and tri-objective optimization of a novel solar 4th cogeneration system for a smart residential building in various climates of Iran

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