Design and Optimization of an Umbrella-Type Shield Based on 3D CFD Simulation Technology

Strojniški vestnik Pub Date : 2023-09-14 DOI:10.5545/sv-jme.2023.644

Longfei Li, Xin He, Taowei Jiao, Yumeng Xiao, Xipan Wei, Wei Li

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Abstract

Mechanical shields can effectively alleviate the problems of low pesticide utilization and severe environmental pollution. This manuscript uses a computational fluid dynamics (CFD) method to investigate the anti-drift mechanism of mechanical shields, study the airflow forms around them, and establish an accurate simulation model. The aerodynamic characteristics of six shields were studied, and their anti-drift effect was compared. Then, the size and working parameters were optimized using the response surface methodology (RSM). Mechanical shields can significantly improve the fog droplet deposition rate (DR) compared with the conventional spray method (no shield), among which the umbrella-type shield has the best effect; optimizing the size and selecting suitable working parameters can increase the DR to 77.31 %. The field trial showed that the DR of the conventional spray method was reduced by 31.9 % at 5 m/s compared with 3 m/s, while the DR of the shield spray method was reduced by only 3.6 % at 5 m/s compared with 3 m/s, which proved the excellent performance of the mechanical shields. The field trial results were consistent with the CFD simulation, and the relative deviation of the DR between the two was within 4 %, so the accuracy and reliability of the CFD simulation model were proved.

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基于三维CFD仿真技术的伞形屏蔽设计与优化

机械防护罩可以有效缓解农药利用率低、环境污染严重的问题。本文采用计算流体力学(CFD)方法对机械防护罩的防漂移机理进行了研究，研究了防护罩周围的气流形态，建立了精确的仿真模型。研究了6种护罩的气动特性，并对其抗漂移效果进行了比较。然后，利用响应面法(RSM)对其尺寸和工作参数进行优化。与常规喷雾方式(无屏蔽)相比，机械屏蔽能显著提高雾滴沉积速率(DR)，其中伞状屏蔽效果最好;通过优化尺寸和选择合适的工作参数，可使回收率达到77.31%。现场试验表明，常规喷雾法在5m /s下的DR比3m /s下降低了31.9%，而屏蔽喷雾法在5m /s下的DR仅比3m /s下降低了3.6%，证明了机械屏蔽的优异性能。现场试验结果与CFD模拟结果吻合较好，两者的相对偏差在4%以内，验证了CFD模拟模型的准确性和可靠性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Strojniški vestnik

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