Application of Response Surface Model for Sizing Solar Thermal Energy System at Residential Scale During the Early Design Stages

M. Abokersh, H. Elayat, Mohamed Osman, M. El-Morsi
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Abstract

In the present study, the design of experiments (DOE) methodology is employed to statistically model and optimize the thermal performance of a forced circulation solar water heating system (FSWHS) with various budget constraints using a small number of simulation trails. The simulation trails are implemented using a model developed in TRNSYS 17 software, and climate conditions of Cairo, Egypt. A sequential approach is used to obtain the optimum system configuration with respect to the budget constraint. The definitive screening design is first utilized to eliminate the insignificant factors and investigate the effect of the quadratic terms. Then, the Box-Behnken design (BBD) is used for developing mathematical models based on multiple regression analysis. Finally, the optimization problem is formulated and solved using the desirability function. The developed mathematical models for the thermal performance responses showed a good agreement with the results obtained in TRNSYS for various budget constraints. This agreement proved the ability of the mathematical models to predict the performance of FSWHS precisely. Furthermore, the optimization methodology can be applied for various types of solar water heating systems, and different renewable energy applications.
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响应面模型在住宅太阳能热系统设计前期的应用
在本研究中,采用实验设计(DOE)方法,通过少量模拟试验,对不同预算约束下强制循环太阳能热水系统(FSWHS)的热性能进行了统计建模和优化。利用TRNSYS 17软件开发的模型和埃及开罗的气候条件实现了模拟轨迹。在预算约束下,采用顺序方法获得最优系统配置。首先利用确定性筛选设计来消除不重要的因素,并研究二次项的影响。然后,采用Box-Behnken设计(BBD)建立基于多元回归分析的数学模型。最后,利用期望函数对优化问题进行了表述和求解。在各种预算约束条件下,所建立的热性能响应数学模型与TRNSYS中得到的结果吻合较好。这种一致性证明了数学模型能够准确地预测FSWHS的性能。此外,该优化方法可应用于各种类型的太阳能热水系统和不同的可再生能源应用。
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