Thermal Analysis of a Fiber Optic Cable for a Vertical Farming Application

S. Cesmeci, Mohammad Towhidul Islam, S. Horowitz
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Abstract

Feeding the existing 7 billion and ever-growing population around the world urges farmers to adopt alternative ways. Research indicates that the demand for alternative farming will only increase as fertile lands become scarcer each and every year. Emerged from this need, “agritecture,” often called vertical farming, has attracted a great deal of attention recently. Vertical farming is centered around growing plants by adopting methods like hydroponic, aeroponic, or aquaponic and staking the layer vertically up to the sky or going deep in the ground. Lighting is the integral component of the vertical farming systems, which can be natural or artificial and should be provided at a specific intensity and spectrum. The world is already in need of energy to tackle the soaring energy demand due to the rising population and industrialization. Researchers have been trying to utilize alternative sources, and the heat and illumination of the sunlight is always the widespread field of interest. In vertical farming, using hybrid solar lighting can also be an appealing approach. However, the fiber optical cable is one of the critical components of this system, which is used to transmit the light to the luminaire. Since this cable plays a vital role in transmitting the power, the exposure of the surface of the cable to different rays from the directed sunlight is of primary concern to avoid any thermal failure. If not designed properly, the temperatures at the inlet of the fiber optical cable can reach to very high values, resulting in both physical and chemical changes in the cable, and in some cases, local burnings. A literature survey revealed that there are only a few studies that dealt with the thermal management of fiber optical cables. In this study, we analyze the thermal behavior of fiber optical cables for a vertical farming application, which was supported by the United States Department of Agriculture SBIR Phase I program. To do that, we adopted a Finite Element Analysis (FEA) based approach. Before carrying out the full simulations, the simulation methodology was verified by replicating an existing study in the literature. Once confirmed, a full parametric sweep analysis was conducted to see the effects of material and geometric properties of the fiber optical cable on the temperature increase at the inlet. This study is novel in the sense that there are no prior studies that targeted the effects of material and geometric properties on the thermal behavior of the fiber optical cables so the users could make the appropriate choices for the cable selection or could custom design their cables for specific lighting conditions. The results were presented and discussed, and future research directions were indicated.
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垂直农业用光缆的热分析
养活全球现有的70亿且不断增长的人口,迫使农民采取其他方式。研究表明,随着肥沃的土地逐年减少,对替代农业的需求只会增加。出于这种需求,“农业”,通常被称为垂直农业,最近引起了极大的关注。垂直农业以采用水培、气培或水培等方法种植植物为中心,并将这一层垂直竖立到天空或深入地下。照明是垂直农业系统的组成部分,它可以是自然的或人工的,应该在特定的强度和光谱下提供。由于人口增长和工业化,世界已经需要能源来应对不断飙升的能源需求。研究人员一直在尝试利用替代能源,而阳光的热量和照明一直是人们广泛感兴趣的领域。在垂直农业中,使用混合太阳能照明也是一种吸引人的方法。然而,光纤电缆是该系统的关键部件之一,用于将光传输到灯具。由于该电缆在传输电力方面起着至关重要的作用,因此电缆表面暴露于直射阳光的不同光线是避免任何热故障的主要关注点。如果设计不当,光纤电缆入口的温度可以达到非常高的值,导致电缆的物理和化学变化,在某些情况下,局部烧毁。一项文献调查显示,只有少数研究涉及光纤电缆的热管理。在本研究中,我们分析了垂直农业应用中光纤电缆的热行为,该应用得到了美国农业部SBIR一期计划的支持。为此,我们采用了基于有限元分析(FEA)的方法。在进行完整的模拟之前,通过复制文献中的现有研究来验证模拟方法。确认后,进行了全参数扫描分析,以查看光纤电缆的材料和几何特性对入口温度升高的影响。这项研究在某种意义上是新颖的,因为之前没有针对材料和几何特性对光纤电缆热行为的影响的研究,因此用户可以为电缆选择做出适当的选择,或者可以根据特定的照明条件定制设计电缆。对研究结果进行了介绍和讨论,并指出了今后的研究方向。
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