Plants use stomata to control the rate of transpiration and photosynthesis. These physiological processes may be also regulated by environmental factors such as humidity, light, temperature, soil moisture, and wind stress.Only a few studies have attempted to investigat the relationship between wind speed and transpiration. Therefore, this study seeks to understand the performances of sap flux under different degrees of wind stress, using the Granier-type sensors to measure sap flux. The study site is located in the Nanjenshan Reserve, Ken-Ting National Park, southern Taiwan. Vegetation in the study area was classified into four habitat types, including windward, leeward, intermediate and valley. Three dominant canopy-tree species slected for this study were Schima superba var. kankaoensis (windward and intermediate type), Castanopsis cuspidate var. carlesii (widely distributed type) and Syzygium buxifolium (windward type). Three individuals (replicates) of each one of the three species were used for the following measurements. Sap flux values were continually measured for each individual over a period of 1.5 years. Sap flux patterns of three tree species were then compared with their circulation changes at different time scales. This study examined the performance of sap flux of three species in the same habitats and compared the performance of sap flux of the same species between windward and intermediate habitats. Photosynthetically active radiation (PAR), temperature, humility, wind speed and wind direction were recorded in the meantime. The relationships between sap flux and environmental factors were analyzed and the importance of wind effects was discussed. The results showed that in sunny days, the daily sap flux of all three species in different habitats had an inverted V-shaped pattern, with the highest flux occurring at noon. However, the daily sap flux decreased dramatically in rainy days, with a relatively smooth curves approximated to y = 0 line. As for yearly sap flux distribution patterns, sum of daily sap flux was higher in the summer than in the winter. Sap flux data of the three species were anti-J distributions. It means that the frequencies of low sap flux values are far higher than the frequencies of high sap flux values. The performance of sap flux during typhoon days was similar to that during rainy day, but sap flux of Castanopsis cuspidate var. carlesii showed an unusual increase in strong wind. In term of the sum of daily sap flux of the three species, Schima superba var. kankaoensis had highest values and Syzygium buxifolium the lowest values. Individuals of same species growing in windward and intermediate habitats had significant differences in sap flux, such that Schima superba var. kankaoensis in the windward habitat had higher sap flux than those in the intermediate habitat, but Castanopsis cuspidate var. carlesii and Syzygium buxifolium had opposite patterns. According to results from plotting the linear relationships between sap flux and environmental factors and the results of stepwise analysis, PAR, temperature and wind speed were the major factors determining the sap flux of Schima superba var. kankaoensis and Syzygium buxifolium. But for Castanopsis cuspidate var. carlesii, there was no obvious relationship between sap flux and wind speed. Due to missing data of vapor pressure difference (VPD), the relationship between sap flux and VPD is still not clarified. The distribution patterns of grading environmental factors and sap flux of three species are different. Sap flux of Schima superba var. kankaoensis was inhibited by the strong winds under low temperature. When the temperature increased, inhibition occurred at a lower wind speed. There was no special pattern between sap flux and wind for Castanopsis cuspidate var. carlesii and Syzygium buxifolium. Only one tree sample of Syzygium buxifolium showed a similar performance to Schima superba var. kankaoensis. It showed that wind speed could inhibit the rising of sap flux at high PAR. Castanopsis cuspidate var. carlesii and Syzygium buxifolium which are widely distributed and windward species are more plastic and able to adapt to their environment due to long-term morphological and physiological modifications. However, Schima superba var. kankaoensis, an intermediate species, had higher sap flux in the windward habitat. The increases of the transpiration of Schima superba var. kankaoensis result the increases of growth increment in the habitat which had sufficient water. This kind of adaptation mechanism could help Schima superba var. kankaoensis to survive in strong wind stress. This study shows that PAR has an important impact on sap flux because there is higher sap flux under PAR conditions (such as noon, sunny day, summer). The differences in sap flux values among three species in the same habitat might be related to differences in leaf structure. Sap flux values of individuals the same species in windward and intermediate habitats were different, suggesting that wind is related to transpiration activities. Among the examined environmental factors, PAR and temperature have greater effects on sap flux, while wind speed only affects the performance of sap flux slightly.