ASHRAE (2005). ASHRAE Handbook—Fundamentals. Atlanta: American Society of Heating, Refrigerating and Air-Conditioning Engineers.
J Babiak, W Olesen B, D Petrás (2007). REHVA Guidebook No 7: Low Temperature Heating and High Temperature Cooling. Brussels: REHVA.
M Bojić, D Cvetković, V Marjanović, M Blagojević, Z Djordjević (2013). Performances of low temperature radiant heating systems. Energy and Buildings, 61: 233–238.
D Cvetković, M Bojić (2014). Optimization of thermal insulation of a house heated by using radiant panels. Energy and Buildings, 85: 329–336.
EN (2004). EN 14240:2004, Ventilation for Buildings—Chilled Ceilings—Testing and Rating. Brussels: European Committee for Standardization.
EN (2007). EN 15251:2007, Indoor Environmental Input Parameters for Design and Assessment of Energy Performance of Buildings Addressing Indoor Air Quality, Thermal Environment, Lighting and Acoustics. Brussels: European Committee for Standardization.
N Fonseca, C Cuevas, V Lemort (2010). Radiant ceiling systems coupled to its environment part 1: Experimental analysis. Applied Thermal Engineering, 30: 2187–2195.
T Imanari, T Omori, K Bogaki (1999). Thermal comfort and energy consumption of the radiant ceiling panel system: Comparison with the conventional all –air system. Energy and Buildings, 30: 167–175.
ISO (2005). ISO 7730:2005, Ergonomics of the Thermal Environment— Analytical Determination and Interpretation of Thermal Comfort Using Calculation of the PMV and PPD Indices and Local Thermal Comfort Criteria. Geneva: International Organization for Standardization.
H Koskela, J Heikkinen, R Niemelä, T Hautalampi (2001). Turbulence correction for thermal comfort calculation. Building and Environment, 36: 247–255.
H Koskela, H Häggblom, R Kosonen, M Ruponen (2011). Flow pattern and thermal comfort in office environment with active chilled beams. HVAC&R Research, 18: 723–736.
H Koskela, H Häggblom, R Kosonen, M Ruponen (2010). Air distribution in office environment with asymmetric workstation layout using chilled beams. Building and Environment, 45: 1923–1931.
J Kurnitski, al. et (2013). REHVA nZEB technical definition and system boundaries for nearly zero energy buildings. REHVA Technical Report 4.
P Mustakallio, Z Bolashikov, K Kostov, A Melikov, R Kosonen (2016). Thermal environment in simulated offices with convective and radiant cooling systems under cooling (summer) mode of operation. Building and Environment, 100: 82–91.
P Mustakallio, T Moilanen, M Ruponen, R Kosonen, K Hagström (2005). Development of CFD model for a cooled beam— Importance of product specific boundary conditions. In: Proceedings of 8th REHVA World Congress Clima, Lausanne, Switzerland.
PV Nielsen, F Allard, HB Awbi, L Davidson, A Schälin (2007). REHVA Guidebook No 10: Computational Fluid Dynamics in Ventilation Design., Brussels: REHVA.
M Rahimi, A Sabernaeemi (2010). Experimental study of radiation and free convection in an enclosure with a radiant ceiling heating system. Energy and Buildings, 42: 2077–2082.
K-N Rhee, KW Kim (2015). A 50 year review of basic and applied research in radiant heating and cooling systems for the built environment. Building and Environment, 91: 166–190.
M Thalfeldt, E Pikas, J Kurnitski, H Voll (2013). Façade design principles for nearly zero energy buildings in a cold climate. Energy and Buildings, 67: 309–321.
Z Tian, Y Ding, S Wang, X Yin, M Wang (2010). Influence of the ventilation system on thermal comfort of the chilled panel system in heating mode. Energy and Buildings, 42: 2360–2364.
J Woollett, J Rimmer, et al. (2015). REHVA-ASHRAE Guidebook No 21: Active and Passive Beam Application Design Guide. Atlanta: American Society of Heating, Refrigerating and Air-Conditioning Engineers.