The increasing global warming and rapid growth of the ski industry have raised higher demands for artificial snowmaking technology and snow quality

with the quality of artificial snowmaking closely linked to the atomization characteristics of snowmaking nozzles.In this paper

the influence of different nozzle interference and gas-liquid mass mixing ratio (GLR) on droplet size distribution and collision mechanism in spray field is studied.The nozzle spacing (D) represents the degree of interference between nozzles

while the gas-liquid mass mixing ratio (GLR) signifies varying degrees of mixing disturbance under identical nozzles.The velocity and size distribution of droplets in the spray field were measured using a laser particle size measuring instrument and a high-speed camera

while the fragmentation and collision of droplets in the spray field were analyzed based on Weber number (We).The results indicate that the axial velocity of double nozzles exceeds that of single nozzles at varying spacing intervals. Specifically

when the nozzle spacing is 10 cm and 15 cm

the peak axial velocities are recorded as 5.6 m/s and 5.5 m/s respectively.The droplet size undergoes a non-monotonic variation with axial distance due to the competing effects of fragmentation and coalescence

initially decreasing before increasing.The interaction between the spray fields of two nozzles enhances droplet collision

resulting in a higher We number compared to that of individual nozzles. The analysis of the flow field of double nozzles under different arrangement conditions reveals that a higher level of uniformity in particle size distribution is observed when GLR=0.10 and D=15cm.