海洋热能转换的系统参数敏感性分析

Q1 Multidisciplinary
.. Rasgianti, R. Adiputra, A. D. Nugraha, R. Sitanggang, Wahyu W. Pandoe, .. Aprijanto, Takeshi Yasunaga, Muhammad A. Santosa
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引用次数: 0

摘要

海洋热能转换(OTEC)是一种利用温暖的表层海水和寒冷的深层海水之间的温差来获取海洋中储存的太阳能的技术。考虑到 OTEC 系统在低温范围内工作,本文通过获取原位温跃层数据并对系统参数进行敏感性分析,对技术资源进行了全面评估。现场温度曲线数据是在印度尼西亚北巴厘岛水域测量的。然后将基于实地测量的温度梯度数据与 HYCOM 联合模型进行了比较。然后,通过单级排序循环,将数据作为 OTEC 功率和效率估算的输入。通过改变工作流体的类型、热交换器的性能和位置来进行分析,以研究系统参数如何影响发电量。由于使用了不同寻常的参数组合,因此很难对所得数据进行多次分析。不过,通过基于参考的分析和计算公式,可以对两个地点的每个参数的敏感性进行评估。结果,氨工作流体提供了系统中最高的净功率输出,但在所有工作流体中效率最低。热交换器在净功率和效率方面的性能与海水质量流量要求是分不开的。海水通过热交换器前后温差为 3°C 的热交换器产生的净功率和效率最高。此外,Bungkulan 站点的净功率输出在水深 400 米和 Celukan Bawang 站点的水深 450 米处达到收敛水平,这与温跃层趋势成正比。Doi: 10.28991/ESJ-2024-08-02-04 全文:PDF
本文章由计算机程序翻译,如有差异,请以英文原文为准。
System Parameters Sensitivity Analysis of Ocean Thermal Energy Conversion
Ocean Thermal Energy Conversion (OTEC) is a technology to harvest the solar energy stored in the ocean by utilizing the temperature difference between warm surface and cold deep seawater. Considering that the OTEC system works in a low-temperature range, the present paper assessed the technical resources comprehensively by acquiring in-situ thermocline data and conducting a sensitivity analysis of the system parameters. The in-situ temperature profile data were measured in the waters of North Bali, Indonesia. The temperature gradient data based on field measurements were then compared with the HYCOM consortium model. The data were then used as input in the OTEC power and efficiency estimation through a single-stage ranking cycle. The analysis was conducted by varying the type of working fluid, the performance of the heat exchanger, and the location to investigate how the system parameters influenced the power produced. Using an unusual combination of parameters made it difficult to analyze the resulting data multiple times. However, with reference-based analysis and the formulation of calculations, the sensitivity of each parameter could be assessed at both locations. As a result, the ammonia working fluid provided the highest net power output of the system but had the lowest efficiency of all working fluids. The heat exchanger performance in terms of net power and efficiency cannot be separated from the seawater mass flow requirement. This referred to the results where the heat exchanger with a temperature difference of 3°C before and after the seawater passed through the heat exchanger and produced the highest net power and efficiency. Additionally, the net power output reached its convergence level at a water depth of 400m for the Bungkulan site and 450m for Celukan Bawang, which was proportional to the thermocline tendency. Doi: 10.28991/ESJ-2024-08-02-04 Full Text: PDF
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来源期刊
Emerging Science Journal
Emerging Science Journal Multidisciplinary-Multidisciplinary
CiteScore
5.40
自引率
0.00%
发文量
155
审稿时长
10 weeks
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