Thermodynamic Efficiency and Control Strategies in Residential Air Conditioning Systems

Authors

  • Evans Abiodun Sunday Bellissima Construction Ltd, Nigeria Author
  • Gbenga Olumide Omoegun Triumph Power and Gas Systems Ltd, Lagos Nigeria Author
  • Mmedo Anietie Essien Independent Researcher, Nigeria Author
  • Odunayo Abosede Oluokun Nigerian Ports Authority, Nigeria Author

DOI:

https://doi.org/10.32628/IJSRCE19339

Keywords:

Thermodynamic efficiency, Intelligent control systems, Renewable integration, Residential cooling, Energy policy, Sustainable HVAC systems

Abstract

The global rise in residential energy demand, primarily driven by the growing reliance on air-conditioning systems, underscores the urgent need to enhance thermodynamic efficiency and control mechanisms to promote sustainable cooling practices. This study critically examined the efficiency performance, control strategies, and policy dimensions influencing the operation and optimization of residential cooling systems. Using a qualitative analytical approach supported by extensive literature synthesis, the research evaluated fundamental thermodynamic principles, explored advanced control technologies, assessed economic feasibility, and reviewed policy frameworks shaping energy efficiency in both developed and developing regions. The analysis revealed that the integration of intelligent control systems—such as predictive, adaptive, and fuzzy logic-based approaches—significantly improves operational stability, energy conservation, and occupant comfort compared to conventional control mechanisms. Moreover, the incorporation of renewable energy sources, particularly solar-assisted and geothermal systems, further enhances system sustainability while mitigating carbon emissions. Findings from the economic evaluation demonstrated that, although initial investment costs remain substantial, lifecycle cost savings and reduced grid dependency justify the adoption of advanced efficiency technologies. However, the study identified critical barriers, including limited policy enforcement, inadequate technical capacity, and insufficient consumer awareness, particularly in African contexts such as Nigeria. The research concludes that achieving optimal performance in residential cooling requires a multidimensional approach integrating technological innovation, economic viability, and robust governance frameworks. It recommends the localization of international efficiency standards, capacity-building programs for HVAC professionals, and stronger incentive mechanisms to accelerate the diffusion of smart and renewable-based cooling systems. Collectively, these measures present a pathway toward sustainable, adaptive, and energy-resilient residential environments globally.

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Published

15-06-2019

Issue

Vol. 3 No. 3 (2019): May-June

Section

Research Articles

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This work is licensed under a Creative Commons Attribution 4.0 International License.

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How to Cite

[1]
Evans Abiodun Sunday, Gbenga Olumide Omoegun, Mmedo Anietie Essien, and Odunayo Abosede Oluokun, “Thermodynamic Efficiency and Control Strategies in Residential Air Conditioning Systems”, Int J Sci Res Civil Engg, vol. 3, no. 3, pp. 52–76, Jun. 2019, doi: 10.32628/IJSRCE19339.