1. IntroductionIn recent years, Cei

1. Introduction
In recent years, Ceiling Radiant Cooling Panels (CRCP) systems have been attracting more and more attention with the advantages in comfort, health, energy conservation and so on. The operating principle of their terminal devices is to make the ceiling a kind of cold radiating surface with lowering temperature, and achieve the purpose of indoor cooling by the radiation heat transfer between the ceiling and other indoor surfaces. CRCP systems originated from Europe and developed on a global scale. There are a series of researches on the heat transfer mechanism studied by scholars from various countries.

Stanley A. Mumma and his team (Stanley A. Mumma, 2001, 2002; Christopher L. Conroy and Stanley A. Mumma, 2001; Jeong and Mumma, 2003a and Jeong and Mumma, 2003b, 2004, 2007; Stanley A. Mumma and Jae-Weon Jeong, 2005; Yizai Xia and Stanley A. Mumma, 2006) fully studied CRCP combined with ventilation systems, and adopted the MRT method provided by ASHRAE Handbook (2012) to calculate the radiation heat transfer between cooling panels and other indoor surfaces. In this method, other indoor surfaces are assumed to one fictitious, finite surface that gives about the same heat flux as the real multisurface case. Morteza M. Ardehali et al. (2004) presented a proof-of-concept formulation and procedure for modeling the heat transfer mechanisms of radiant conditioning panels with considerations for the occupant in a thermal zone. The mathematical model was established based on steady state net-radiation method. Refet Karadag (2009a, 2009b) focused on radiative and convective heat transfer coefficients at the ceiling and the relation between them in a cooled ceiling room. The radiative heat transfer modeling was based on the network method. Francesco Causone et al. (2009) evaluated experimentally the heat transfer coefficients between radiant ceiling and room in typical conditions of occupancy of an office or residential building, and MRT method was adopted to calculate radiation heat transfer. Mostafa Rahimi et al. (2010) investigated the participation of the radiation and free convection in the heat transfer from the heated ceiling surface of a room to other internal surfaces, and found that more than 90% of the heat is transferred by radiation. A model based on the steady state net-radiation method was employed to compute the radiation exchanges between internal surfaces of the elements. Fonseca, 2011a, Fonseca, 2011b, Fonseca Díaz and Cuevas, 2010c, Fonseca et al., 2010a and Fonseca et al., 2010b developed a model of radiant ceiling panels in heating or cooling modes, and the behavior of the radiant ceiling system and the interactions with its environment were experimentally and numerically evaluated. Radiant panels were considered as dynamic-state heat exchanger connected to a detailed lumped dynamic model of the building (supported by the R-C network). L. Fontana (2011) experimentally studied the thermal performance of radiant heating floor systems in furnished enclosed space on a scale model. Their calculation of radiation heat transfer was based on the equivalent radiation heat exchange coefficient method, which simplified fourth power of temperature to a linear relationship.

To sum up, previous researches involving radiation heat transfer in the room equipped with CRCP mostly adopt MRT method, steady state net-radiation method or network method (just based on the net-radiation method) (Ephraim M. Sparrow and R. D. Cess, 1970), and there are few researches involving non-steady state radiation heat transfer. If solving this kind of problem by the mentioned methods, we need to calculate the equations repeatedly, which is a wasting of computer memory. Moreover, the mentioned methods fail to solve the situation that the temperatures of some interior surfaces are lacking but the heat flows are known. This research embarks from the fundamental theory, and establishes the model of non-steady state radiation heat transfer in the room equipped with Ceiling Radiant Cooling Panels.