Development of a new graphical tool for calculation of exergy losses to design and optimisation of sub-ambient processes

Abstract This paper presents new graphical tools, which can quickly identify all thermal exergy losses occurring in process design particularly in condensers/evaporators of low-temperature processes. Although the Ω –H diagram is a powerful tool for getting insights about exergy losses in a Heat Exchanger Network, the calculation of the enclosed area is not straightforward due to the non-linearity of the curve. The Omega Composite Curves and Omega Grand Composite Curve developed in this research are new graphical tools that can be applied to any process, including sub-ambient processes. These curves are linear and all enclosed areas have a rectangular shape. So, all thermal exergy losses can readily be calculated and also necessary modifications to enhance the efficiency of refrigeration systems, either in new design or retrofit study can graphically be suggested. To demonstrate the capability of the new graphical tools, two ammonia refrigeration cycles (one single-stage and one three-stage) have been designed to fulfil the cooling demand of a sub-ambient process and achieve minimum shaft work requirements. The exergy loss associated with condensers/evaporators in the refrigeration cycle is directly calculated from the diagrams. Combining the new tools with mathematical programming, a new systematic procedure for the design and optimisation of sub-ambient processes is presented. A case study of a natural gas liquefaction process was used to demonstrate the application of the proposed procedure resulted in 24.9% lower shaft work consumption. This improvement was obtained by changing the composition of the mixed refrigerant. Also, in the third case study, the exergy loss within the refrigeration cycle of an industrial ammonia plant decreased by 15.31% by applying the suggested procedure to optimise the refrigeration levels.

[1]  N. Tahouni,et al.  Comparison of stochastic methods with respect to performance and reliability of low‐temperature gas separation processes , 2010 .

[2]  Tatiana Morosuk,et al.  Advanced exergetic analysis : Approaches for splitting the exergy destruction into endogenous and exogenous parts , 2009 .

[3]  ChangKyoo Yoo,et al.  Exergy, exergo-economic, and exergy-pinch analyses (EXPA) of the kalina power-cooling cycle with an ejector , 2018, Energy.

[4]  Jiří Jaromír Klemeš,et al.  New directions in the implementation of Pinch Methodology (PM) , 2018, Renewable and Sustainable Energy Reviews.

[5]  Truls Gundersen,et al.  New Graphical Representation of Exergy Applied to Low Temperature Process Design , 2013 .

[6]  Jin-Kuk Kim,et al.  Cooling System Design , 2002, ITherm 2002.

[7]  Bodo Linnhoff,et al.  Shaftwork targets for low-temperature process design , 1992 .

[8]  Truls Gundersen,et al.  An Extended Pinch Analysis and Design procedure utilizing pressure based exergy for subambient cooling , 2007 .

[9]  K. Siemanond,et al.  Combined Exergy-pinch Analysis to Improve Cryogenic Process , 2015 .

[10]  Robin Smith,et al.  Optimal Synthesis of Mixed-Refrigerant Systems for Low-Temperature Processes , 2002 .

[11]  Nassim Tahouni,et al.  Development of a New Graphical Tool for Calculation of Exergy Losses in Sub-Ambient Processes , 2019 .

[12]  N. Tahouni,et al.  Benchmarking of olefin plant cold-end for shaft work consumption, using process integration concepts , 2017 .

[13]  Emilio Manzanares-Papayanopoulos,et al.  Diagnosis and redesign of power plants using combined Pinch and Exergy Analysis , 2014 .

[14]  Robin Smith,et al.  Chemical Process: Design and Integration , 2005 .

[15]  Mehdi Mehrpooya,et al.  A comprehensive approach toward utilizing mixed refrigerant and absorption refrigeration systems in an integrated cryogenic refrigeration process , 2018 .

[16]  Assaad Zoughaib,et al.  A MILP algorithm for utilities pre-design based on the Pinch Analysis and an exergy criterion , 2015, Comput. Chem. Eng..

[17]  Nassim Tahouni,et al.  Improving energy efficiency of an Olefin plant – A new approach , 2013 .

[18]  X. X. Zhu,et al.  Combining pinch and exergy analysis for process modifications , 1997 .

[19]  Peng Yen Liew,et al.  Combined Pinch and exergy numerical analysis for low temperature heat exchanger network , 2018, Energy.

[20]  F. Pourfayaz,et al.  Advanced exergy analysis of heat exchanger network in a complex natural gas refinery , 2019, Journal of Cleaner Production.

[21]  M. H. Panjeshahi,et al.  Retrofit of ammonia plant for improving energy efficiency , 2008 .

[22]  Mostafa Mafi,et al.  A novel approach for operational optimization of multi-stage refrigeration cycles in gas refineries , 2017 .

[23]  Ali Ghannadzadeh,et al.  Exergy aided pinch analysis to enhance energy integration towards environmental sustainability in a chlorine-caustic soda production process , 2017 .

[24]  Nassim Tahouni,et al.  Integration of a gas turbine with an ammonia process for improving energy efficiency , 2013 .

[25]  Jiaqiang Jing,et al.  Advanced exergy analyses of modified ethane recovery processes with different refrigeration cycles , 2020 .