In order to improve the energy structure and reduce the GHG emission per capita, promoting renewable energy applications such as the solar water heating system (SWHS) has become an essential national policy. However, regional characteristics can greatly affect the applicability and potential benefits of using SWHS. This study thus proposed a method for assessing the regional applicability and environmental and economic benefits of SWHS in Taiwan. To facilitate various regional analyses, the entire country is divided into four SWHS development regions based on the level of radiation in each region and administrative boundaries. Previous studies generally implemented their analyses based on the annual solar radiation that may overestimate the energy benefit because, for a SWHS application, the solar radiation energy captured today generally can not be preserved until the next day, even the radiation is excessively high. Therefore, this study determines effective days based on whether the potential heat output, estimated from the water temperature and solar radiation in each region, of each day is enough to run a SWHS or not. The energy benefit of a SWHS is then estimated based on the number of effective days, instead of on annual radiation. The potential benefit for installing two storage tanks is also analyzed. A procedure is established for analyzing the applicability of a SWHS in each region based on its potential cost benefit. Seven scenarios are established according to the development status, the ratio for achieving the national policy target, subsidy, heat transfer rate, fixed and maintenance cost, and discount rate. The environmental and economic benefits among scenarios are also estimated and compared. Under current situation, the environmental benefit, in term of eCO2 reduction, for substituting electricity, diesel and natural gas are 37,175, 18,721 and 14,157 tons, respectively. If the target of the national SWHS development policy is achieved, the environmental benefit is expected to increase about 50%. The payback period without subsidy in the high radiation and island areas is between 18.9 and 21.2 years, while for other areas it is more than 24 years. If the initial fixed cost is decreased by 10%-30% and providing subsidies, the payback period can be shortened to 12.8-7.9 years. If the heat transfer rate increases 7%-20%, it can increase 9-20 effective days. When the discount rate is increased from 1.86% to 3% -5%, the payback period can be shorten about 9.1%-17.5%. The results show that promoting SWHS in high radiation areas is effective, but for other areas with less radiation the payback period is still too long. These scenario results are expected to facilitate related decision analyses for developing SWHS in different regions.