Thermodynamic optimisation and analysis of four Kalina cycle layouts for high temperature applications

Abstract The Kalina cycle has seen increased interest in the last few years as an efficient alternative to the conventional steam Rankine cycle. However, the available literature gives little information on the algorithms to solve or optimise this inherently complex cycle. This paper presents a detailed approach to solve and optimise a Kalina cycle for high temperature (a turbine inlet temperature of 500 °C) and high pressure (over 100 bar) applications using a computationally efficient solution algorithm. A central receiver solar thermal power plant with direct steam generation was considered as a case study. Four different layouts for the Kalina cycle based on the number and/or placement of the recuperators in the cycle were optimised and compared based on performance parameters such as the cycle efficiency and the cooling water requirement. The cycles were modelled in steady state and optimised with the maximisation of the cycle efficiency as the objective function. It is observed that the different cycle layouts result in different regions for the optimal value of the turbine inlet ammonia mass fraction. Out of the four compared layouts, the most complex layout KC1234 gives the highest efficiency. The cooling water requirement is closely related to the cycle efficiency, i.e., the better the efficiency, the lower is the cooling water requirement.

[1]  Charles H. Marston,et al.  Gas turbine bottoming cycles: Triple-pressure steam versus Kalina , 1995 .

[2]  M. He,et al.  A review of research on the Kalina cycle , 2012 .

[3]  Mehmet Kanoglu,et al.  Thermodynamic and economic analysis and optimization of power cycles for a medium temperature geothermal resource , 2014 .

[4]  Eva Thorin Power cycles with ammonia-water mixtures as working fluid , 2000 .

[5]  Fredrik Haglind,et al.  Thermodynamic evaluation of the Kalina split-cycle concepts for waste heat recovery applications , 2014 .

[6]  S. C. Kaushik,et al.  Energy and exergy analysis and optimization of Kalina cycle coupled with a coal fired steam power plant , 2013 .

[7]  Daniel G. Friend,et al.  A Helmholtz Free Energy Formulation of the Thermodynamic Properties of the Mixture {Water + Ammonia} , 1998 .

[8]  Yiping Dai,et al.  Parametric analysis and optimization of a Kalina cycle driven by solar energy , 2013 .

[9]  Charles H. Marston,et al.  Parametric Analysis of the Kalina Cycle , 1989 .

[10]  Fredrik Haglind,et al.  Multiple regression models for the prediction of the maximum obtainable thermal efficiency of organic Rankine cycles , 2014 .

[11]  P. Nag,et al.  Exergy analysis of the Kalina cycle , 1998 .

[12]  Fredrik Haglind,et al.  Performance analysis of a Kalina cycle for a central receiver solar thermal power plant with direct steam generation , 2014 .

[13]  Chul Ho Han,et al.  Effects of ammonia concentration on the thermodynamic performances of ammonia–water based power cycles , 2012 .

[14]  Sirko Ogriseck,et al.  Integration of Kalina cycle in a combined heat and power plant, a case study , 2009 .

[15]  Mounir B. Ibrahim,et al.  A Kalina Cycle Application for Power Generation , 1993 .

[16]  Xuanming Su,et al.  Energy–exergy analysis and optimization of the solar-boosted Kalina cycle system 11 (KCS-11) , 2014 .

[17]  A. I. Kalina,et al.  Combined-Cycle System With Novel Bottoming Cycle , 1984 .

[18]  Costante Mario Invernizzi,et al.  Heat recovery from Diesel engines: A thermodynamic comparison between Kalina and ORC cycles , 2010 .