On-site measured performance of a radiant floor cooling/heating system in Xi’an Xianyang International Airport

•Performances of radiant floor (RF) cooling and heating in an airport are measured.•High-T cooling and low-T heating are realized in the RF system.•Cooling and heating capacity of the RF is 30–40W/m2 and 30–70W/m2 respectively.•Cooling capacity of RF is improved to over 100W/m2 with high-intensity s...

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Published in:Solar energy 2014-10, Vol.108, p.274-286
Main Authors: Zhao, Kang, Liu, Xiao-Hua, Jiang, Yi
Format: Article
Language:English
Subjects:
Air conditioning. Ventilation
Air-conditioning
Applied sciences
Electrical engineering. Electrical power engineering
Electrical power engineering
Energy
Energy conservation
Energy efficiency
Energy. Thermal use of fuels
Exact sciences and technology
Heating, air conditioning and ventilation
Indoor thermal environment
Large space building
Material and general technologies
Natural energy
Power networks and lines
Radiant floor cooling/heating
Radiation
Solar energy
Solar radiation
Space heating. Hot water
Techniques, equipment. Control. Metering
Temperature distribution
Users connections and in door installation
Water temperature
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container_title Solar energy
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creator Zhao, Kang
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Jiang, Yi
description •Performances of radiant floor (RF) cooling and heating in an airport are measured.•High-T cooling and low-T heating are realized in the RF system.•Cooling and heating capacity of the RF is 30–40W/m2 and 30–70W/m2 respectively.•Cooling capacity of RF is improved to over 100W/m2 with high-intensity solar radiation.•The RF system provides a comfortable environment and improved energy-efficiency compared with jet ventilation. In large space buildings such as airports, radiant floor systems are an attractive alternative to conventional all-air jet ventilation systems due to their advantages in thermal comfort and energy efficiency. This paper focuses on the operating performance of the radiant floor system in Terminal 3 of Xi’an Xianyang International Airport, the first airport terminal in China to adopt radiant floors for cooling. In summer, the typical cooling capacity of the radiant floor is 30–40W/m2 with a mean chilled water temperature of 18°C; this range increases to 110–140W/m2 with solar radiation of 120–170W/m2. The incremental effect of the solar radiation on the cooling capacity of radiant floor is analyzed with simple calculation methods. In winter, the radiant floor provides a heating capacity of 30–70W/m2 with a hot water temperature of 35–40°C, which is sufficient to satisfy the heating requirement. Compared with the jet ventilation system adopted in Terminal 2 of the same airport, indoor thermal comfort is significantly improved with the radiant floor system in Terminal 3 in both cooling and heating modes. Moreover, the novel system’s indoor air temperature distribution throughout the whole space and its utilization of high-temperature chilled water and low-temperature hot water reveal its potential for energy conservation.
doi_str_mv 10.1016/j.solener.2014.07.012
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subjects Air conditioning. Ventilation
Air-conditioning
Applied sciences
Electrical engineering. Electrical power engineering
Electrical power engineering
Energy
Energy conservation
Energy efficiency
Energy. Thermal use of fuels
Exact sciences and technology
Heating, air conditioning and ventilation
Indoor thermal environment
Large space building
Material and general technologies
Natural energy
Power networks and lines
Radiant floor cooling/heating
Radiation
Solar energy
Solar radiation
Space heating. Hot water
Techniques, equipment. Control. Metering
Temperature distribution
Users connections and in door installation
Water temperature
title On-site measured performance of a radiant floor cooling/heating system in Xi’an Xianyang International Airport
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