2019
DOI: 10.3390/en12040693
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Air Distribution and Air Handling Unit Configuration Effects on Energy Performance in an Air-Heated Ice Rink Arena

Abstract: Indoor ice rink arenas are among the foremost consumers of energy within building sector due to their exclusive indoor conditions. A single ice rink arena may consume energy of up to 3500 MWh annually, indicating the potential for energy saving. The cooling effect of the ice pad, which is the main source for heat loss, causes a vertical indoor air temperature gradient. The objective of the present study is twofold: (i) to study vertical temperature stratification of indoor air, and how it impacts on heat load … Show more

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Cited by 12 publications
(13 citation statements)
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“…The measurements did not imply any significant differences in temperature or relative humidity depending on the location over the ice pad, either corner or centre, in agreement with Taebnia et al (2019).…”
Section: Indoor Air Measurementssupporting
confidence: 79%
See 3 more Smart Citations
“…The measurements did not imply any significant differences in temperature or relative humidity depending on the location over the ice pad, either corner or centre, in agreement with Taebnia et al (2019).…”
Section: Indoor Air Measurementssupporting
confidence: 79%
“…The accurate measurements, energy balance analysis and analytical temperature profile in the ice pad presented in this work can constitute useful tools for increasing the energy efficiency in the ice hockey arenas, since the ice thickness covers a role in the overall energy demand, as suggested by Somrani et al (2008), and control of the indoor air stratification is capable of reducing the energy consumption appreciably, as demonstrated by Taebnia et al (2019).…”
Section: Discussionmentioning
confidence: 94%
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“…In Finland, the reported average temperature and humidity inside the arenas were 3.5°C–8.8°C and 64.5%–82%, respectively 139,142 . Salonen et al 12 listed the following means to reduce exposure in ice arenas: 1) the use of electric resurfacers instead of combustion engine powered resurfacers; 2) retrofitting emission control technology in propane‐fueled resurfacers as an efficient temporary option to reduce engine emissions; 3) mechanical ventilation at a reasonable air exchange rate (0.25‐0.5 h ‐1 ) during opening hours; 4) personnel training to understand the risks associated with poor maintenance practices if combustion engine resurfacers are used; 5) if the CO concentration is >20 mg/m 3 (17.46 ppm) or the NO 2 concentration is >150 µg/m 3 , ventilation should be increased; 6) at CO concentration >60 mg/m 3 (52.37 ppm) or NO 2 concentration >2000 µg/m 3 , ice arena users and spectators should be evacuated if the elevated pollutant level cannot be effectively reduced within 15‐30 minutes.…”
Section: Resultsmentioning
confidence: 99%