3.3.5. Mosquito Trapping Device Result Analysis after Optimization
After completing the wind field and light field simulations and actual measurements, the subsequent step entails physically capturing mosquitoes to determine the optimal conditions for mosquito trapping. This process encompasses capturing mosquitoes, categorizing and aggregating those captured by each mosquito-collecting component, calculating the average value, and subsequently conducting comparisons across each group to ascertain the optimized mosquito-trapping system and its components. Finally, the data derived from the light and wind fields are correlated to elucidate the rationale behind optimizing the mosquito trapping system. Below, the schematic diagram depicting the mosquito capture environment is presented, accompanied by the following conditions:
Capture Time: 5:00 PM to 10:00 PM
Capture Location: Grass adjacent to the classroom
Height of Mosquito Trap Placement: 50 cm from the ground
Distance between two groups of Mosquito Trap Lamps: 6 feet
Experiment Period: Four days
Data Statistics Cycle: Once a day
Due to the restricted availability of grassland mosquitoes, only two units were employed in each experiment. The experimental selection process of the mosquito trapping device is illustrated in
Figure 12. To this end, two groups, each comprising short and long units, were selected for comparison. In Experiment 1, both 0 cm and 3 cm units were deployed to capture mosquitoes. Subsequently, the collected mosquitoes were quantified and compared to ascertain the superior mosquito trapping capability. This determination then dictated the selection of experimental units for Experiment 3. In the subsequent phase, the 5 cm and 7 cm units were utilized to capture mosquitoes, and the gathered data were statistically analyzed to identify the unit with superior mosquito trapping efficacy. Following this, the mosquito trapping system underwent optimization, and a detailed analysis was conducted to elucidate the factors contributing to the enhanced mosquito trapping ability. The experimental flow chart is depicted in the accompanying figure.
The comparison between the 0 cm and 3 cm units in catching mosquitoes under specified experimental conditions is outlined in this chapter. The results depicted in
Figure 13 and
Table 13 indicate a clear superiority of the 3 cm unit over the 0 cm unit in terms of mosquito-capturing efficiency. Notably, the images predominantly show gnats and clothes moths for the 0 cm unit, while Aedes aegypti mosquitoes are prevalent for both units. Analysis of the mosquito data table further confirms that the 3 cm unit captures a higher number of mosquitoes across various types compared to the 0 cm unit, indicating its superior efficiency. In Experiment 1, it was established that among the shorter sizes, the 3 cm unit exhibits better mosquito-catching capabilities. Additionally, simulation results presented demonstrate favorable metrics such as wind speed enhancement extension distance, light intensity (cd), luminous area (cm
2), and average mosquito count for the 3 cm unit compared to the 0 cm unit. The only parameter where the 0 cm unit outperforms the 3 cm unit is the light divergence angle half-opening angle (θ). Nonetheless, despite this, as numerous conditions favor the 3 cm unit, it remains uncertain which specific condition contributes the most to optimizing the mosquito trap. Further experiments are warranted to validate these findings and ascertain the optimal parameters for mosquito trapping.
Utilizing the 0 cm and 3 cm units, mosquito trapping was compared under the experimental conditions delineated at the onset of this chapter. The experimental findings are presented in
Figure 13 and detailed in
Table 14 and
Table 15.
Experiment 2 involved using 5 cm and 7 cm units to capture mosquitoes under conditions identical to those in Experiment 1. The experimental results are depicted in
Figure 14 and summarized in
Table 16 and
Table 17. Owing to the consistent location, the types of mosquitoes captured were similar to those in Experiment 1. Notably, the 5 cm unit outperformed the 7 cm unit across various mosquito species. This indicates that the mosquito-trapping efficiency of the 5 cm unit surpasses that of the 7 cm unit. Moreover, after substituting the simulation results with the mosquito trapping data, it was observed that while the luminous area of the 5 cm unit was inferior to that of the 7 cm unit, it excelled in light divergence angle (θ) and light intensity (cd). Therefore, based on Experiments 1 and 2, it can be inferred that light intensity is the primary factor contributing to the optimization of mosquito-trapping efficiency.
In experiments 1 and 2, we designated the 3 cm and 5 cm units as the experimental units for Experiment 3. Subsequently, these two units were utilized to capture mosquitoes. The experimental conditions remained consistent with those of the preceding experiments. The results of these experiments are presented in
Figure 15 and
Table 18 and
Table 19. It is apparent from the data that there exists a discernible discrepancy in the number of mosquitoes captured by the 3 cm unit compared to the 5 cm unit. Henceforth, upon scrutiny of
Table 18, it becomes apparent that the 5 cm unit displays superior efficacy in ensnaring moths and mosquitoes, while the 3 cm unit excels particularly in capturing diminutive insects. After this analysis, the simulation outcomes are transcribed into
Table 19, elucidating that the 3 cm unit surpasses the 5 cm unit exclusively regarding the light divergence angle (θ). The practical execution of mosquito entrapment demonstrates proficiency in ensnaring diminutive insects. Moreover, the 5 cm unit exhibits notable performance in light intensity, luminous area, and wind speed. Concerning actual mosquito capture, it is evident that the 5 cm unit excels in capturing both moths and mosquitoes.
Following Experiments 1 and 2, it was established that the principal factor influencing the optimization of mosquito-trapping efficiency is the light intensity within the mosquito trapping system. However, upon the culmination of Experiment 3, it was discerned that while light intensity remains paramount, its significance is not absolute. From an experimental standpoint, it was observed that the light intensity is robust. Yet, the light divergence angle is insufficiently broad, and the attraction radius for mosquitoes may be limited, thereby diminishing the efficacy of capturing smaller insects. Conversely, if the light divergence angle is extensive but the light intensity and other pertinent conditions are inadequate, it may diminish the likelihood of capturing mosquitoes and moths. Consequently, in our practical endeavors of mosquito capture, two components were identified as optimizing capture efficiency: the 3 cm component and the 5 cm machine part. The 3 cm component is apt for capturing diminutive insects, whereas the 5 cm part demonstrates superior efficacy in capturing moths and mosquitoes.