Your search keyword '"Triki, Zakaria"' showing total 3 results

1. Exergy Analysis of a Solar Vapor Compression Refrigeration System Using R1234ze(E) as an Environmentally Friendly Replacement of R134a.

Author

Triki, Zakaria, Selloum, Ahmed, Chiba, Younes, Tahraoui, Hichem, Mansour, Dorsaf, Amrane, Abdeltif, Zamouche, Meriem, Kebir, Mohammed, and Zhang, Jie

Subjects

REFRIGERATION & refrigerating machinery, EXERGY, ELECTRICAL energy, HEAT transfer, HEAT recovery, HEAT flux

Abstract

Refrigeration plays a significant role across various aspects of human life and consumes substantial amounts of electrical energy. The rapid advancement of green cooling technology presents numerous solar-powered refrigeration systems as viable alternatives to traditional refrigeration equipment. Exergy analysis is a key in identifying actual thermodynamic losses and improving the environmental and economic efficiency of refrigeration systems. In this study exergy analyze has been conducted for a solar-powered vapor compression refrigeration (SP-VCR) system in the region of Ghardaïa (Southern Algeria) utilizing R1234ze(E) fluid as an eco-friendly substitute for R134a refrigerant. A MATLAB-based numerical model was developed to evaluate losses in different system components and the exergy efficiency of the SP-VCR system. Furthermore, a parametric study was carried-out to analyze the impact of various operating conditions on the system's exergy destruction and efficiency. The obtained results revealed that, for both refrigerants, the compressor exhibited the highest exergy destruction, followed by the condenser, expansion valve, and evaporator. However, the system using R1234ze(E) demonstrated lower irreversibility compared to that using R134a refrigerant. The improvements made with R1234ze are 71.95% for the compressor, 39.13% for the condenser, 15.38% for the expansion valve, 5% for the evaporator, and 54.76% for the overall system, which confirm the potential of R1234ze(E) as a promising alternative to R134a for cooling applications. [ABSTRACT FROM AUTHOR]

Published

2024

2. Optimizing Sustainability: Exergoenvironmental Analysis of a Multi-Effect Distillation with Thermal Vapor Compression System for Seawater Desalination

Author

Fergani, Zineb, primary, Triki, Zakaria, additional, Menasri, Rabah, additional, Tahraoui, Hichem, additional, Zamouche, Meriem, additional, Kebir, Mohammed, additional, Zhang, Jie, additional, and Amrane, Abdeltif, additional

Published

2024

3. Enhancing Hygrothermal Performance in Multi-Zone Constructions through Phase Change Material Integration.

Author

Abboud, Abir, Triki, Zakaria, Djeffal, Rachid, Bekkouche, Sidi Mohammed El Amine, Tahraoui, Hichem, Amrane, Abdeltif, Assadi, Aymen Amin, Khozami, Lotfi, and Zhang, Jie

Subjects

HYGROTHERMOELASTICITY, PHASE change materials, NUMERICAL analysis, HUMIDITY

Abstract

As buildings evolve to meet the challenges of energy efficiency and indoor comfort, phase change materials (PCM) emerge as a promising solution due to their ability to store and release latent heat. This paper explores the transformative impact of incorporating PCM on the hygrothermal dynamics of multi-zone constructions. The study focuses on analyzing heat transfer, particularly through thermal conduction, in a wall containing PCM. A novel approach was proposed, wherein the studied system (sensitive balance) interacts directly with a latent balance to realistically define the behavior of specific humidity and mass flow rates. In addition, a numerical model implemented in MATLAB software has been developed to investigate the effect of integrating PCM on the hygrothermal balances inside the building. The obtained results indicate a consistent response in internal temperatures, specific humidity, and mass flow rates, with temperature differences ranging from 5°C to 13°C and a maximum phase shift of 13 h. In addition, the findings provided valuable insights into optimizing the design and performance of multi-zone constructions, offering a sustainable pathway for enhancing building resilience and occupant well-being. [ABSTRACT FROM AUTHOR]

Published

2024