Feasibility Study and Design of a Seawater Air-Conditioning System for a University Building in Fiji

Volume 6: Energy Pub Date : 2022-10-30 DOI:10.1115/imece2022-96152

Muzammil Ali, Reemal D. Prasad, M. R. Ahmed

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Abstract

The demand for space cooling in Fiji is increasing rapidly due to a high infrastructure development rate in the country. Seawater air conditioning is a solution to the problem of space cooling using renewable energy. In this work, a feasibility study and design of a SWAC system for a university building is carried out. The feasibility study included the cooling load calculations, the availability of seawater and the location of the building. The cooling load was estimated using CAMEL software which came to be about 509 kW. Local bathymetry charts were studied to determine the depth of ocean to be 1000 m closest to the shore at which water temperatures about 6°C can be obtained. The distance from shore at which the cold water was available was approximately 12 km. A 1:15 scaled down model of the building was constructed to find the ideal chilled water supply rate and temperature. Optimal design parameters were found to be a chilled water temperature of 7°C and a cold-water flow rate of 100L/min. A temperature of 23°C was achieved inside the building after about 15 mins. The design phase of the system included the entire buildings supply and return duct system divided among 5 AHUs. The length of the seawater suction pipeline was estimated using the depth and the distance to be around 12 km. The diameter of the seawater suction pipe was optimized using cost of pipe installation and pumping power to be 0.4m, corresponding to a pumping power of 5 kW. A heat exchanger with a capacity of 500 kW, like the total cooling load of the project was selected to transfer heat between the seawater loop and the chilled water loop. The chilled water pumping power was calculated after the design of the full chilled water supply pipeline to be 4 kW. The total cost for the implementation of the SWAC system for the Marine Sciences building was estimated to be $1.04M and the payback period was estimated to be 13.8 years compared to a conventional split-type system.

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斐济某大学大楼海水空调系统的可行性研究与设计

由于斐济基础设施发展速度快，斐济对空间降温的需求正在迅速增加。海水空调是利用可再生能源解决空间冷却问题的一种方法。本文对某大学建筑的SWAC系统进行了可行性研究和设计。可行性研究包括冷负荷计算，海水的可用性和建筑物的位置。使用CAMEL软件估计冷却负荷约为509千瓦。研究了当地的测深图，以确定离海岸最近的海洋深度为1000米，在那里可以获得约6°C的水温。离海岸有冷水的地方大约有12公里。建造了一个1:15的建筑物模型，以找到理想的冷冻水供应速率和温度。优化设计参数为冷冻水温度为7℃，冷水流量为100L/min。大约15分钟后，建筑物内的温度达到23°C。系统的设计阶段包括整个建筑的供回风管道系统，分为5个ahu。利用深度和距离估算海水吸入管道的长度约为12公里。以管道安装成本和泵送功率为0.4m，对应泵送功率为5kw，对吸海水管直径进行优化。选择与项目总冷负荷相当的500kw热交换器在海水回路和冷冻水回路之间进行换热。经冷冻水全供管路设计后计算，冷冻水泵送功率为4kw。与传统的分体式系统相比，海洋科学大楼swc系统的实施总成本估计为104万美元，投资回收期估计为13.8年。

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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Volume 6: Energy

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