苹果园防冻多孔冠层传热的CFD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.15550
Weiyun Hua, P. Heinemann, Long He, Wenan Yuan
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The average percentage of the protected canopy increased by 108.2% when the heater output intensity increased to 477,000 KJ·h-1 and 46.0% when the heater output velocity increased to 15 m·s-1. However, the percentage of the protected canopy showed diminishing returns as the heater output intensity and velocity increased. The simulated heat dissipation time was linearly related to the heating duration, which can be utilized to determine the reheating time for mobile heating. The outcome of the study can be beneficial for making effective frost protection decisions in apple orchards. 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引用次数: 0

摘要

利用Ansys Fluent软件对某苹果园的对流换热进行了数值模拟。得到了不同加热方式下不同的加热形态和对流换热系数。模拟了加热器输出强度、输出速度和加热角度对加热效果的影响。加热时间和散热时间是移动加热的关键。摘要霜冻事件给农业造成巨大的经济损失。防冻方法,特别是加热,已经在对寒冷敏感的作物中实施了几千年。虽然传统的加热策略通常是有效的,但由于缺乏空间温度信息,传统的加热策略可能是不充分或浪费的,导致保护不足或加热不均匀的问题。计算流体动力学(CFD)建模通过预测模拟环境中空间流速、压力和温度分布等各种过程,已被广泛用于模拟流体流动、传热和传质。建立并验证了模拟苹果园气流传热的三维CFD模型,分析了加热器输出强度、输出速度、加热角度、加热时间等因素对苹果园气流传热的影响。经过验证的模型有效地预测了三种代表性加热方案(加热器朝向树排的角度为0°、45°和90°)下冠层内部空间温度随时间的变化,平均均方根误差(RMSE)为2.6°C。模拟结果表明,45°角度加热器的加热效果最好,平均保护层百分比最大(72.3%),而0°和90°角度加热器的平均保护层百分比最大(33.1%)。当加热器输出强度增加到47.7万KJ·h-1时,保护冠层的平均百分比增加了108.2%,当加热器输出速度增加到15 m·s-1时,保护冠层的平均百分比增加了46.0%。然而,随着加热器输出强度和速度的增加,被保护冠层的百分比呈递减趋势。模拟的散热时间与加热时间呈线性关系,可用于确定移动加热的再加热时间。研究结果可为苹果园制定有效的防冻决策提供参考。关键词:冠层,计算流体力学,防霜,传热,多孔介质建模
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CFD Simulation of Porous Canopy Heat Transfer in Apple Orchard-Based Frost Protection
Highlights Convective heat transfer in an apple orchard was simulated by Ansys Fluent. The various heating patterns and convective heat transfer coefficients under different heating schemes were obtained. The heating effects of heater output intensity, output velocity, and heating angle were simulated. The heating duration and heat dissipation time were critical for mobile heating. Abstract. Frost events cause high economic losses in agriculture. Frost protection methods, particularly heating, have been implemented in cold-sensitive crops for millennia. Although often effective, traditional heating strategies can be insufficient or wasteful due to a lack of spatial temperature information, resulting in inadequate protection or uneven heating problems. Computational fluid dynamics (CFD) modeling has been widely used to simulate fluid flow, heat, and mass transfer by predicting various processes such as spatial flow velocity, pressure, and temperature distribution within a simulated environment. A three-dimensional CFD model for simulating airflow and heat transfer in an apple orchard was developed and validated, with the effects of heater output intensity and output velocity, heating angle, and heating duration analyzed. The validated model effectively predicted the spatial temperature changes over time inside the canopy for three representative heating schemes (heaters angled 0°, 45°, and 90° toward a tree row) with an average root mean square error (RMSE) of 2.6 °C. The simulated results show that the heating scheme of heaters angled 45° was the most effective, resulting in the largest average percentage of the protected canopy (72.3%), compared with heaters angled 0° (33.1%) and 90° (56.5%). The average percentage of the protected canopy increased by 108.2% when the heater output intensity increased to 477,000 KJ·h-1 and 46.0% when the heater output velocity increased to 15 m·s-1. However, the percentage of the protected canopy showed diminishing returns as the heater output intensity and velocity increased. The simulated heat dissipation time was linearly related to the heating duration, which can be utilized to determine the reheating time for mobile heating. The outcome of the study can be beneficial for making effective frost protection decisions in apple orchards. Keywords: Canopy, Computational fluid dynamics, Frost protection, Heat transfer, Porous media modeling.
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