Sensitivity analysis of the thermal performance of radiant and convective terminals for cooling buildings

•Thermal performance dependent on the ventilation characteristics and temperature stratification.•Efficiency of convective terminal depends on the convective flow in the room.•Radiant terminals perform better than convective terminals at high air change rate/outdoor temperature.•View factor between...

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Published in:Energy and buildings 2014-10, Vol.82, p.482-491
Main Authors: Le Dréau, J., Heiselberg, P.
Format: Article
Language:English
Subjects:
Active chilled beam
Air temperature stratification
Applied sciences
Beams (radiation)
Building technical equipments
Buildings
Buildings. Public works
Chilled
Civil Engineering
Comfort
Computation methods. Tables. Charts
Construction durable
Convective heat transfer coefficient
Cooled ceiling
Cooled wall
Cooling
Cooling need
Emitters
Engineering Sciences
Environmental engineering
Exact sciences and technology
External envelopes
Floor cooling
Floor. Ceiling
Heat transfer
Sensitivity analysis
Structural analysis. Stresses
Terminals
Ventilation. Air conditioning
Wall. Partition
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description •Thermal performance dependent on the ventilation characteristics and temperature stratification.•Efficiency of convective terminal depends on the convective flow in the room.•Radiant terminals perform better than convective terminals at high air change rate/outdoor temperature.•View factor between activated element and people should be optimised.•Large comfort differences in the room with the cooled floor. Heating and cooling terminals can be classified in two main categories: convective terminals (e.g. active chilled beam, air conditioning) and radiant terminals. The mode of heat transfer of the two emitters is different: the first one is mainly based on convection, whereas the second one is based on both radiation and convection. In order to characterise the advantages and drawbacks of the different terminals, steady-state simulations of a typical office room have been performed using four types of terminals (active chilled beam, radiant floor, wall and ceiling). A sensitivity analysis has been conducted to determine the parameters influencing their thermal performance the most. The air change rate, the outdoor temperature and the air temperature stratification have the largest effect on the cooling need (maintaining a constant operative temperature). For air change rates higher than 0.5 ACH, differences between terminals can be observed. Due to their higher dependency on the air change rate and outdoor temperature, convective terminals are generally less energy effective than radiant terminals. The global comfort level achieved by the different systems is always within the recommended range, but differences have been observed in the uniformity of comfort.
doi_str_mv 10.1016/j.enbuild.2014.07.002
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Heating and cooling terminals can be classified in two main categories: convective terminals (e.g. active chilled beam, air conditioning) and radiant terminals. The mode of heat transfer of the two emitters is different: the first one is mainly based on convection, whereas the second one is based on both radiation and convection. In order to characterise the advantages and drawbacks of the different terminals, steady-state simulations of a typical office room have been performed using four types of terminals (active chilled beam, radiant floor, wall and ceiling). A sensitivity analysis has been conducted to determine the parameters influencing their thermal performance the most. The air change rate, the outdoor temperature and the air temperature stratification have the largest effect on the cooling need (maintaining a constant operative temperature). For air change rates higher than 0.5 ACH, differences between terminals can be observed. 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Heating and cooling terminals can be classified in two main categories: convective terminals (e.g. active chilled beam, air conditioning) and radiant terminals. The mode of heat transfer of the two emitters is different: the first one is mainly based on convection, whereas the second one is based on both radiation and convection. In order to characterise the advantages and drawbacks of the different terminals, steady-state simulations of a typical office room have been performed using four types of terminals (active chilled beam, radiant floor, wall and ceiling). A sensitivity analysis has been conducted to determine the parameters influencing their thermal performance the most. The air change rate, the outdoor temperature and the air temperature stratification have the largest effect on the cooling need (maintaining a constant operative temperature). For air change rates higher than 0.5 ACH, differences between terminals can be observed. 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Charts</subject><subject>Construction durable</subject><subject>Convective heat transfer coefficient</subject><subject>Cooled ceiling</subject><subject>Cooled wall</subject><subject>Cooling</subject><subject>Cooling need</subject><subject>Emitters</subject><subject>Engineering Sciences</subject><subject>Environmental engineering</subject><subject>Exact sciences and technology</subject><subject>External envelopes</subject><subject>Floor cooling</subject><subject>Floor. Ceiling</subject><subject>Heat transfer</subject><subject>Sensitivity analysis</subject><subject>Structural analysis. Stresses</subject><subject>Terminals</subject><subject>Ventilation. Air conditioning</subject><subject>Wall. 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Public works</topic><topic>Chilled</topic><topic>Civil Engineering</topic><topic>Comfort</topic><topic>Computation methods. Tables. Charts</topic><topic>Construction durable</topic><topic>Convective heat transfer coefficient</topic><topic>Cooled ceiling</topic><topic>Cooled wall</topic><topic>Cooling</topic><topic>Cooling need</topic><topic>Emitters</topic><topic>Engineering Sciences</topic><topic>Environmental engineering</topic><topic>Exact sciences and technology</topic><topic>External envelopes</topic><topic>Floor cooling</topic><topic>Floor. Ceiling</topic><topic>Heat transfer</topic><topic>Sensitivity analysis</topic><topic>Structural analysis. Stresses</topic><topic>Terminals</topic><topic>Ventilation. Air conditioning</topic><topic>Wall. 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source ScienceDirect Journals
subjects Active chilled beam
Air temperature stratification
Applied sciences
Beams (radiation)
Building technical equipments
Buildings
Buildings. Public works
Chilled
Civil Engineering
Comfort
Computation methods. Tables. Charts
Construction durable
Convective heat transfer coefficient
Cooled ceiling
Cooled wall
Cooling
Cooling need
Emitters
Engineering Sciences
Environmental engineering
Exact sciences and technology
External envelopes
Floor cooling
Floor. Ceiling
Heat transfer
Sensitivity analysis
Structural analysis. Stresses
Terminals
Ventilation. Air conditioning
Wall. Partition
title Sensitivity analysis of the thermal performance of radiant and convective terminals for cooling buildings
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