For several critical problems associated with the conventional green roof, green roof is currently not widely promoted in this country. Therefore, this research group had developed the Bucket hollow green roof (BHGR), a new green roof that is expected to be more cost-effective with great flexibility in maintenance. This study was initiated for evaluating the capability and effectiveness in reducing heat transfer and energy savings for the PET-bottle based hollow green roof (PHGR), a new green roof developed in this group. To carry out this study, a PHGR was installed on the roof of a campus building, and a conventional green roof (GR) and a BHGR were also installed. And a bare roof (CR) in a similar size was simultaneously monitored for comparing their thermal reduction efficiencies, including the effectiveness of the air layers created by both PHGR and BHGR. Similar to the previous study, data such as solar radiation, weather, soil volumetric water content, water level, heat flux, and temperature were monitored and the data were transferred via Internet to a remote computer in our research laboratory. Based on the data collected, the differences of four roofs for temperatures and heat fluxes in different levels were compared and analyzed. Also, the U-values of the roofs and the energy saving of applying the green roofs were estimated by the one-dimensional heat flux equation method. Energy balance models for PHGR and GR were developed by modifying the models previously developed for the BHGR and the CR. Comparative analyses were implemented based on the results obtained from the models. According to the experimental results for BHGR, PHGR, GR and CR, All green roofs can effectively reduce heat transfer. The performance of the BHGR and PHGR is superior to that of the GR in surface temperature and degree hour analyses. The U-values of the BHGR and the PHGR were estimated to be 0.93 and 0.96 W/m2K under ventilation assumption and 0.84 and 0.86 W/m2K under poor ventilation assumption. The U-value of the GR was estimated to be 1.26 W/m2K. The annual energy savings, as estimated by the one-dimensional heat flux equation, for the BHGR, PHGR and GR are 5.1 ~ 5.4, 4.7 ~ 5.0, and 3.8 kWh/m2, respectively. For the conventional roof with a better insulated layer, the annual energy savings are approximately 2.4 ~ 2.6, 2.2 ~ 2.4 and 1.6 kWh/m2. From the energy balance analyses for roofs, the sensible heats of the BHGR, PHGR, GR and CR are about 10.3, 13.8, 22.3 and 21.6% of the net radiation.