Optimizing production efficiencies of hot water units using building energy simulations - Trade-off between Legionella pneumophila contamination risk and energy efficiency

The energy needed for domestic hot water represents an important share in the total energy use of well-insulated and airtight buildings. One of the main reasons for this high energy demand is that hot water is produced at temperatures above 60°C to mitigate the risk of contaminating the hot water sy...

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Bibliographic Details
Published in:E3S web of conferences 2019-01, Vol.111, p.4053
Main Authors: Van Kenhove, Elisa, De Backer, Lien, Laverge, Jelle
Format: Article
Language:English
Subjects:
Airtightness
Case studies
Computer simulation
Contamination
Controllers
Drinking water
Energy
Energy conservation
Energy consumption
Energy demand
Energy efficiency
Heat
Heat exchangers
Heat pumps
Heating systems
High temperature
Hot water heating
Legionella pneumophila
Legionnaires' disease bacterium
Residential energy
Risk reduction
Solar collectors
Temperature
Temperature effects
Water heating
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Summary:The energy needed for domestic hot water represents an important share in the total energy use of well-insulated and airtight buildings. One of the main reasons for this high energy demand is that hot water is produced at temperatures above 60°C to mitigate the risk of contaminating the hot water system with Legionella pneumophila . However, this elevated temperature is not necessary for most domestic hot water applications, and has a negative effect on the efficiency of hot water production units. A simulation model has been developed which proposes an alternative to this constant 60°C by predicting the Legionella pneumophila concentration dynamically throughout the hot water system. Based on this knowledge, a hot water controller is added to the simulation model that sets a lower hot water comfort temperature in combination with heat shocks. In this paper, the simulation model is used to estimate the energy saving potential in a case study building, at the level of the heat production system by reaching higher production efficiencies. Three different production units, namely an electric boiler, heat pump and solar collector have been investigated. The controller is expected to become an alternative for the current, energy intensive, high temperature tap water heating systems.
ISSN:2267-1242
2555-0403
2267-1242
DOI:10.1051/e3sconf/201911104053