散贮粮食中磷化氢运动的数值模拟

IF 1.2 4区 农林科学 Q3 AGRICULTURAL ENGINEERING Journal of the ASABE Pub Date : 2023-01-01 DOI:10.13031/ja.15378
S. Elsayed, M. Casada, R. Maghirang, Mingjun Wei, D. Maier
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引用次数: 0

摘要

建立CFD模型,揭示掩体中磷化氢运动的详细机制。评价影响粮仓中磷化氢分布的因素。就掩体中磷化氢熏蒸的最佳管理做法提出建议。摘要地堡储存是一种廉价的,因此是小麦中长期储存的常用方法。为了控制仓仓储存库的虫害,通常使用磷化铝(AlP)片剂释放的磷化氢(PH3)熏蒸剂,特别是在澳大利亚。为了使熏蒸有效,必须确保整个掩体的PH3浓度达到致死水平。由于掩体暴露在环境条件下,整个掩体会产生温度梯度,从而产生自然对流,将PH3从熏蒸点周围的区域移动到整个掩体。本研究采用计算流体力学(CFD)模拟研究了自然对流对掩体熏蒸的影响。该模型通过公开的基准测试和具有吸附和泄漏的全尺寸桶的现场实验进行了验证。研究了PH3释放点位置、掩体形状、掩体方向、泄漏、吸附、环境温度波动和PH3三维运动的影响。结果与实验数据吻合良好,并为掩体PH3熏蒸的最佳管理实践提供了各种建议。结果表明,仅靠扩散和自然对流对掩体内PH3的扩散是不够的。篷布翻滚对PH3行为的影响有待进一步研究。关键词:仓,仓,CFD,熏蒸,自然对流,磷化氢,多孔介质,模拟,吸附,物种迁移,小麦
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Numerical Simulation of Phosphine Movement in Bulk-Stored Grain
Highlights Develop a CFD model that reveals the detailed mechanisms of phosphine movement in bunkers. Evaluate factors that impact phosphine distribution in grain bunkers. Provide recommendations for best management practices for phosphine fumigation in bunkers. Abstract. Bunker storage is an inexpensive and, thus, popular method for medium- and long-term storage of wheat. To control insect infestations in bunker storage, phosphine (PH3) fumigant, released from aluminum phosphide (AlP) tablets, is commonly used, especially in Australia. For fumigation to be effective, a lethal concentration of PH3 throughout the bunker must be ensured. Because bunkers are exposed to ambient conditions, temperature gradients are created throughout the bunker, resulting in natural convection currents that move PH3 from areas around the fumigation points to the entire bunker. This research used computational fluid dynamics (CFD) simulation to investigate the effect of natural convection on fumigation in bunkers. The model was validated against published benchmarks and a field experiment with a full-scale bin with sorption and leakage. The effects of PH3 release points location, bunker shape, bunker orientation, leakage, sorption, ambient temperature fluctuation, and PH3 motion in 3D were studied. Results agreed well with the experimental data and provided various recommendations for best management practices for PH3 fumigations in bunkers. Results showed that diffusion and natural convection solely are insufficient in spreading out PH3 within bunkers. Further research is needed on the effects of tarpaulin billowing in relation to PH3 behavior. Keywords: Bin, Bunker, CFD, Fumigation, Natural convection, Phosphine, Porous media, Simulation, Sorption, Species transport, Wheat.
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