Abstract
Conventional Kalina cycle-based geothermal power plants are designed with a fixed working point determined by the local maximum ambient temperature during the year. A previous study indicated that the plant’s annual average thermal efficiency would be improved if the ammonia mass fraction of the Kalina cycle could be tuned to adapt to the ambient conditions. In this paper, another sliding condensation pressure method is investigated. A theoretical model is set up and then a numerical program is developed to analyze the cycle performance. The condensation pressure adjustment in accordance to the changing ambient temperature has been numerically demonstrated under various ammonia-water mixture concentrations. The results indicate that the Kalina cycle using sliding condensation pressure method can achieve much better annual average thermal efficiency than a conventional Kalina cycle through matching the cycle with the changing ambient temperature via controlling condensation pressure. Furthermore, the sliding condensation pressure method is compared with the composition tuning method. The results show that the annual average efficiency improvement of the sliding condensation pressure method is higher than that of the composition tuning method.
Highlights
Geothermal energy has many advantages such as weatherproof, base-load power, high stability and reliability, less land usage, and less ecological effect [1]
In order to address this problem, this paper theoretically investigates the efficiency improvement of the KSG-1 Kalina cycle system using the sliding condensation pressure method and the results are compared with that of the composition tuning method
This paper investigates the efficiency improvement of a Kalina cycle with sliding condensation pressure method
Summary
Geothermal energy has many advantages such as weatherproof, base-load power, high stability and reliability, less land usage, and less ecological effect [1]. With the progress of technology, power generation from low-temperature geothermal energy becomes economically attractive [2]. The Kalina cycle uses a zeotropic mixture as the working fluid (normally ammonia-water) and can be applied for low-temperature geothermal power generation [4,5]. Hua et al designed a triple-pressure ammonia-water power cycle and the results showed that the power recovery efficiency was about 16.6% higher than that of a steam Rankine cycle [6]. Fallah used an advanced exergy method to analyze a Kalina cycle system 11 (denoted as KCS-11 hereafter) [8]. Ma et al compared three advanced absorption power cycles with KCS-11 system in terms of power output, energy and exergy efficiencies for lowtemperature heat sources [9]
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
