Entropy-Driven Environmental Impact Assessment of Condensate-Induced Irreversibility in Integrated Building Energy Systems
Mehmet Ziya Söğüt, Zafer Utlu

TL;DR
This paper explores how entropy production from condensate in building energy systems can help assess environmental impacts and improve energy management.
Contribution
The study introduces a novel entropy-driven method to evaluate condensate-induced inefficiencies in integrated building energy systems.
Findings
The average exergy efficiency for distribution lines is 22%, with exergy extinction at 78%.
Entropy generation potential due to condensation load is 65.3%, and pollution potential is 64.9%.
The target energy efficiency level for condensate management is set at 33.5%.
Abstract
In multifunctional and high-energy-density integrated buildings, energy performance and environmental impacts are affected by the environmental conditions in which they are located. Entropy production, which is an output of exergy analysis in energy performance, offers a new evaluation area for energy management in this context. In the study developed for this purpose, the condensate line formed in the steam distribution lines of an integrated building was modeled, and the possible inefficiency potential of the condensate load formed and the usability of the approach developed over entropy production were suggested by energy management. Entropy production due to exergy destruction of distribution lines derived from condensate pump data in the integrated building was evaluated with two environmental indices developed. According to the analysis, the average exergy efficiency for the…
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Taxonomy
TopicsThermodynamic and Exergetic Analyses of Power and Cooling Systems · Sustainability and Ecological Systems Analysis · Refrigeration and Air Conditioning Technologies
