Leafy vegetables are important food crops in Taiwan and are mainly grown in greenhouses and net houses. Because of its large output, machines are required to harvest the crops. However, current harvesters cannot effectively collect the cut leafy vegetables by blowing them. Accordingly, this study redesigned the air exit duct to improve collection efficiency of vegetable leaves. The turbulent flow model was first determined by comparing the actual measurement with the simulation model data. Next, the turbulent flow model was used to construct the air duct model of the harvester, appearance parameters were modified, and computational fluid dynamics software was employed to analyze whether the air duct model facilitates smooth air flow, thereby identifying optimal parametric values for the appearance of the air duct. By comparing the actual measurement with the simulation results, this study found that the realizable k-epsilon model is more suitable for simulating the turbulent flow model of the harvester duct, which was then used in subsequent analysis. The simulation results show that reducing the number of auxiliary pipes can effectively increase the outlet discharge velocity. With the same number of auxiliary pipes, maintaining a fixed distance between the auxiliary pipes or between the first and last auxiliary pipe had a negligible influence on outlet discharge velocity. In addition, modifying the length of the auxiliary pipe did not significantly increase the outlet discharge velocity. However, reducing the diameter of the outlet of the auxiliary pipe markedly increased the outlet discharge velocity. Marked increases in outlet discharge velocity were also observed when the auxiliary pipe was positioned 60 degrees to the horizontal plane and when the angle between the auxiliary pipe and the main pipe is 150 degrees. Based on the simulation results, a custom model was constructed, comprising a main pipe (length = 600 mm, diameter = 50 mm) and 5 auxiliary pipes (length = 95 mm, diameter = 12 mm). The distance between the auxiliary pipes was 105 mm. The first auxiliary pipe was 90 mm from the duct inlet and was positioned 60 degrees to the horizontal plane and 150 degrees to the main pipe. The simulation results show that the discharge velocity of the proposed model increased by 735.216%, an increase of 745.92% compared to the original model.