Microexplosions have been reported to occur during the combustion process of mixtures of biodiesel and alcohol fuels. However, we have found that they can be prevented if the standing time of the fuel sample is sufficiently long. In the experiments based on suspending droplets and free droplets, the mechanisms of microexplosions were studied by investigating the burning process of droplets composed of various proportions of low-C alcohols and biodiesel. Before ignition, we found that many heterogeneous sites, which appeared similar to drops, emerged from the droplet surface and subsequently merged to a bigger one and deposited at the bottom of the droplet. The diameter of this heterogeneous drop increased with the humidity of the ambience. At the same humidity, the experiments showed that the merged heterogeneous drop of biodiesel/methanol was largest and the smallest one was generated by the biodiesel/isopropanol; the one in-between was generated by biodiesel/ethanol. These heterogeneous sites were likely caused by the hygroscopic characteristics of alcohol fuels, which were supposed to mix well with the fuel of biodiesel and treated as a miscible blend in the first place. However, the miscibility was destroyed by absorbed water and phase separation occurred. On the other hand, the interior heterogeneous drop vanished after a sufficient standing time, and consequently microexplosion were not found during the whole combustion process. For the mixture fuel with methanol, which has higher tendency of water absorption, about 2.5 minutes of standing time was needed to remove the heterogeneous drop. Nonetheless, only ~1.5 minutes was measured for the mixture fuel with isopropyl, which has lower propensity to absorb water. The heterogeneous site inside the blended fuel droplet was concluded to be the primary cause of microexplsion during combustion process. In contrast, elimination of the heterogeneous site in the test droplets can prohibit the appearance of microexplosion.