The thermochemical system using ammonia as energy storage carrier is investigated in this study. A mathematical model was developed to predict the behavior of both reactors in the ammonia-based closed-loop system. For the importance of the dissociation and formation process in the system, the model focused only on the solar and the synthesis reactors. The study shows that maintaining the best mass flow rate is important for achieving the maximum ammonia dissociation and formation processes and as a result the maximum thermal output. Operating the reactors at higher pressure than suggested increases the formation of ammonia at the synthesis; however, it lowers the thermal output of the system.

中文翻译：

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氨太阳能和合成反应器的数学模型

本研究对以氨为储能载体的热化学系统进行了研究。建立了数学模型来预测基于氨的闭环系统中两个反应器的行为。对于解离和形成过程在系统中的重要性，该模型仅关注太阳能和合成反应器。研究表明，保持最佳质量流速对于实现最大的氨离解和形成过程以及因此获得最大的热输出至关重要。在比建议的更高的压力下操作反应器会增加合成中氨的形成。但是，它降低了系统的热量输出。