Based on the classical nucleation theory, a Time-Temperature-Transformation curve of Zr61Ti2Cu25Al12 alloy was constructed, and its critical cooling rate Rc≈63K/s was estimated and modified. Its reliability was evaluated using the glass-forming ability criteria, and the dominance of nucleation rate I and growth rate U on the crystallization mechanism in different supercooled liquid regions was explained. By combining flash differential scanning calorimetry with conventional thermal analysis, six orders of magnitude (10^-2~10^4 K/s) of heating rate changes were achieved for the Zr61Ti2Cu25Al12 amorphous alloy, demonstrating the kinetic behavior of supercooled liquid dependence on heating rate over an ultra-wide range: 1. The dependence between heating rate and characteristic temperatures follows the Vogel-Fulcher-Tammann equation; 2. The small change in fragility coefficient (m=30~41) means that its supercooled liquid structure changes relatively smoothly with temperature, exhibiting a certain "strong" liquid behavior, making the alloy have a certain glass-forming ability. This study provides technical guidance and theoretical basis for the preparation of Zr61Ti2Cu25Al12 amorphous alloy, especially for the plastic forming in the supercooled liquid region and the formulation of heat treatment process.