Towards Autonomous Solar Driven Agricultural Greenhouses in Qatar - Integration with Solar Cooling

2019 7th International Renewable and Sustainable Energy Conference (IRSEC) Pub Date : 2019-11-01 DOI:10.1109/IRSEC48032.2019.9078285

A. Hassabou, M. Khan

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引用次数: 6

Abstract

Qatar is a peninsula located in the Middle East and classified as a hot subtropical desert based on its geographical location and climate. The weather is hot and humid in the summer, but mild in the winter. Aridity is the general characteristic of the country, while natural vegetation such as trees and shrubs can be found in some regions. The hot climate and high humidity in summer as well as aridity in Qatar impose major challenges for expansion in the agricultural sector. The government of Qatar has been and will continue to support local food production through the Qatar National Food Security Program (QNFSP) and other initiatives to develop the agricultural sector to the maximum realizable extent. The focus of this research work is on design, modeling and optimization of small to large-scale agricultural greenhouses for improving their energy and water use efficiency and equipping them with solar PV systems. The solar PV is integrated with the structure of greenhouse, as a roof mounted system, without compromising the supply of daylight and required solar energy for plants growth. The ultimate goal is to develop a Passive Solar Greenhouse (PSGH) design that reduces the cooling load drastically and integrate it with solar cooling to cover 100% of the cooling load. The aim of the optimized PSGH design is to maintain favorable crops growing conditions inside a greenhouse such as temperature, humidity, daylight, ventilation and minimize the cooling load and energy consumption. Five different sizes of pitched roof greenhouses with the optimized PSGH design (28mx8m, 28mx20m, 28mx50m, 28m×100m and 28mx150m) were modeled and compared with the conventional greenhouse design in terms of their dynamic cooling loads and overall energy consumption. The analysis showed that the cooling load of the PSGH design has been reduced by approximately 74%, while over 77% reduction in annual energy consumption has been achieved, compared to a conventional greenhouse design.

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朝向自主太阳能驱动的农业温室在卡塔尔-集成与太阳能冷却

卡塔尔是位于中东的一个半岛，根据地理位置和气候被划分为炎热的亚热带沙漠。夏天的天气又热又潮湿，但冬天却很暖和。干旱是这个国家的普遍特征，而在一些地区可以找到树木和灌木等自然植被。卡塔尔炎热的气候和夏季的高湿度以及干旱对农业部门的扩张构成了重大挑战。卡塔尔政府一直并将继续通过卡塔尔国家粮食安全计划(QNFSP)和其他举措支持当地粮食生产，以最大限度地发展农业部门。本研究工作的重点是小型到大型农业温室的设计、建模和优化，以提高其能源和水的利用效率，并配备太阳能光伏系统。太阳能光伏与温室结构相结合，作为屋顶安装系统，不影响日光的供应和植物生长所需的太阳能。最终目标是开发一种被动式太阳能温室(PSGH)设计，它可以大幅降低冷却负荷，并将其与太阳能冷却相结合，以覆盖100%的冷却负荷。优化PSGH设计的目的是在温室内保持有利的作物生长条件，如温度、湿度、日光、通风，并最大限度地减少冷负荷和能源消耗。以优化后的5个不同尺寸的坡顶温室(28mx8m、28mx20m、28mx50m、28m×100m和28mx150m)为模型，与传统设计进行了动态冷负荷和总能耗的比较。分析表明，与传统温室设计相比，PSGH设计的冷却负荷降低了约74%，而年能耗降低了77%以上。

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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2019 7th International Renewable and Sustainable Energy Conference (IRSEC)

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