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Clean Technologies and Environmental Policy

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01-08-2015 | Original Paper

Polygeneration performance assessments: multi-dimensional viewpoint

Authors: Kuntal Jana, Sudipta De

Published in: Clean Technologies and Environmental Policy | Issue 6/2015

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Abstract

Performance metrics of a system with single input and single output is straight forward and is generally termed as ‘efficiency’. However, for systems with multiple outputs, defined performance metrics has to include effects of all outputs on a rational basis. For systems with both multiple inputs and outputs such definition is even more complicated. Polygeneration is the integration of multiple utility outputs with one or more inputs for better performance. The better performance may again be assessed from different aspects, e.g., thermodynamic, economic, social, etc. Performance metrics of polygeneration is not unique. It depends on type of systems as well as objective of evaluation of it. In this paper, several possible performance parameters for polygeneration are discussed. Evaluation of performance is also tested with multi-dimensional viewpoints. Simulation results of two polygeneration schemes are used to show case studies for these defined performance parameters. Relative performance of polygeneration schemes with different fuel inputs is presented to show the performance variation of these schemes with multi-dimensional viewpoints.

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Aspen Plus^® (2014) Aspen Technology, Inc., Cambridge. www.aspentech.com. Accessed 04/07/2014

Aspen Tech (2011) Aspen physical property system 11.1. Aspen Technology, Inc., Cambridge

Beith R (2011) Small and micro combined heat and power (CHP) systems. Woodhead Publishing, CambridgeCrossRef

Bracco S, Delfino F, Pampararo F, Robba M, Rossi M (2014) A mathematical model for the optimal operation of the University of Genoa Smart Polygeneration Microgrid: evaluation of technical, economic and environmental performance indicators. Energy 64:912–922CrossRef

Brau J-F, Morandin M, Berntsson T (2013) Hydrogen for oil refining via biomass indirect steam gasification: energy and environmental targets. Clean Technol Environ Policy 15:501–512CrossRef

Darwish NA, Al-Hashimi SH, Al-Mansoori AS (2008) Performance analysis and evaluation of a commercial absorption–refrigeration water–ammonia (ARWA) system. Int J Refrig 31:1214–1223CrossRef

Dincer I, Naterer GF (2010) Assessment of exergy efficiency and Sustainability Index of an air–water heat pump. Int J Exergy 7(1):37–50CrossRef

EIA (2013) Ethanol price. Energy Information Administration. www.eia.gov/todayinenergy/prices. Accessed 02/09/2013

Erenstein O, Thorpe W, Singh J, Varma A (2007) Crop–livestock interactions and livelihoods in the Indo-Gangetic Plains, India: a regional synthesis. CIMMYT, ILRI and RWC, New Delhi. repsitory.cimmyt.org/xmlui/bitstream/handle. Accessed 05/05/2014

Eveloy V, Rodgers P, Popli S (2014) Trigeneration scheme for a natural gas liquids extraction plant in the Middle East. Energy Convers Manag 78:204–218CrossRef

Freschi F, Giaccone L, Lazzeroni P, Repetto M (2013) Economic and environmental analysis of a trigeneration system for food-industry: a case study. Appl Energy 107:157–172CrossRef

Henao CA (2005) Simulation and evaluation of chemical processes. Universidad Pontificia Bolivariana (in Spanish), Antioquia, Colombia

Horlock JH (1987) Cogeneration—combined heat and power (CHP). Pergamon Press, Oxford

Hossain AK, Thorpe R, Vasudevan P, Sen PK, Critoph RE, Davies PA (2013) Omnigen: providing electricity, food preparation, cold storage and pure water using a variety of local fuels. Renew Energy 49:197–202CrossRef

IEA (2011) World energy outlook. International Energy Agency, Paris

IEA/OECD (2008) CO₂ capture and storage: a key carbon abatement option. France

Jana K, De S (2014) Biomass integrated gasification combined cogeneration with or without CO₂ capture—a comparative thermodynamic study. Renew Energy 72:243–252CrossRef

Jana K, De S (2015) Polygeneration using agricultural waste: thermodynamic and economic feasibility study. Renew Energy 74:648–660CrossRef

Jing X, Zheng D (2014) Effect of cycle coupling-configuration on energy cascade utilization for a new power and cooling cogeneration cycle. Energy Convers Manag 78:58–64CrossRef

Kanoglu M, Dincer I (2009) Performance assessment of cogeneration plants. Energy Convers Manag 50:76–81CrossRef

Klemeš J, Varbanov PS (2013) Process Intensification and Integration: an assessment. Clean Technol Environ Policy 15:417–422CrossRef

Klemeš J, Friedler F, Bulatov I, Varbanov P (2011) Sustainability in the process industry. McGraw Hill, New York

Knoope MMJ, Meerman JC, Ramírez A, Faaij APC (2013) Future technological and economic performance of IGCC and FT production facilities with and without CO₂ capture: combining component based learning curve and bottom-up analysis. Int J Greenh Gas Control 16:287–310CrossRef

Kotas TJ (1985) The exergy method of thermal plant analysis. Butterworths, London

Kyriakarakos G, Dounis AI, Rozakis S, Arvanitis KG, Papadakis G (2011) Polygeneration microgrids: a viable solution in remote areas for supplying power, potable water and hydrogen as transportation fuel. Appl Energy 88:4517–4526CrossRef

Luo C, Zhang N, Lior N, Lin H (2011) Proposal and analysis of a dual-purpose system integrating a chemically recuperated gas turbine cycle with thermal sea water desalination. Energy 36:3791–3803CrossRef

Maraver D, Uche J, Royo J (2012) Assessment of high temperature organic Rankine cycle engine for polygeneration with MED desalination: a preliminary approach. Energy Convers Manag 53:108–117CrossRef

Meerman JC, Ramirez A, Turkenburg WC, Faaij APC (2011) Performance of simulated flexible integrated gasification polygeneration facilities. Part A: technical-energetic assessment. Renew Sustain Energy Rev 15:2563–2587CrossRef

MNRE (2013) Biomass power and cogeneration programme. Ministry of New and Renewable Energy, Government of India. www.mnre.gov.in/schemes/grid-connected/biomass-powercogen/. Accessed 05/05/2014

Ng KS, Zhang N, Sadhukhan J (2012) Decarbonised coal energy system advancement through CO₂ utilisation and polygeneration. Clean Technol Environ Policy 14:443–451CrossRef

Ong’ro AO, Ugursal VI, Taweel A, Blamire K (1995) Simulation of combined cycle power plants using the ASPEN Plus Shell. Heat Recovery Syst CHP 15(2):105–113CrossRef

Puig-Arnavat M, Bruno JC, Coronas A (2014) Modeling of trigeneration configurations based on biomass gasification and comparison of performance. Appl Energy 114:845–856CrossRef

Rackley SA (2010) Carbon capture and storage. Butterworth–Heinemann, Oxford

Serra LA, Lozano MA, Ramos J, Ensinas AV, Nebra SA (2009) Polygeneration and efficient use of natural resources. Energy 34:575–586CrossRef

Spriggs HD, Brant B, Rudnick D, Hall KR, El-Halwagi MM (2009) Sustainability metrics for highly integrated biofuel production facilities. In: Design for energy and environment: proceedings of the 7th International conference on the Foundations of Computer-Aided Process Design. CRC Press, pp 399–404. Boca Raton, USA

Szargut J, Morris DR, Steward FR (1988) Exergy analysis of thermal, chemical, and metallurgical processes. Hemisphere Publishing, Washington, DC

Tock L, Maréchal F (2012) Co-production of hydrogen and electricity from lignocellulosic biomass: process design and thermo-economic optimization. Energy 45:339–349CrossRef

Tonon S, Brown MT, Luchi F, Mirandola A, Stoppato A, Ulgiati S (2006) An integrated assessment of energy conversion processes by means of thermodynamic, economic and environmental parameters. Energy 31:149–163CrossRef

Verhelst S (2014) Recent progress in the use of hydrogen as a fuel for internal combustion engines. Int J Hydrog Energy 39:1071–1085CrossRef

Yi Q, Feng J, Li WY (2012) Optimization and efficiency analysis of polygeneration system with coke-oven gas and coal gasified gas by Aspen Plus. Fuel 96:131–140CrossRef

Yi Q, Feng J, Wu Y, Li W (2014) 3E (energy, environmental, and economy) evaluation and assessment to an innovative dual-gas polygeneration system. Energy 66:285–294CrossRef

Title: Polygeneration performance assessments: multi-dimensional viewpoint
Authors: Kuntal Jana
Sudipta De
Publication date: 01-08-2015
Publisher: Springer Berlin Heidelberg
Published in: Clean Technologies and Environmental Policy / Issue 6/2015
Print ISSN: 1618-954X
Electronic ISSN: 1618-9558
DOI: https://doi.org/10.1007/s10098-014-0885-6

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