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Exergy based model predictive control of an integrated dual fuel engine and a waste heat recovery system

This study showcases a new exergy based model predictive control (XMPC) framework designed to maximize the fuel conversion efficiency of an internal combustion engine (ICE); when the ICE is integrated with a waste heat recovery (WHR) system. Consequently, mathematical models are developed for the in...

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Published in:	Control engineering practice 2023-06, Vol.135, p.105510, Article 105510
Main Authors:	Reddy, C.R., Bonfochi Vinhaes, V., Naber, J.D., Robinett, R.D., Shahbakhti, M.
Format:	Article
Language:	English
Subjects:	Exergy based model predictive control Internal combustion engine Organic rankine cycle Waste heat recovery
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creator	Reddy, C.R. Bonfochi Vinhaes, V. Naber, J.D. Robinett, R.D. Shahbakhti, M.
description	This study showcases a new exergy based model predictive control (XMPC) framework designed to maximize the fuel conversion efficiency of an internal combustion engine (ICE); when the ICE is integrated with a waste heat recovery (WHR) system. Consequently, mathematical models are developed for the integrated ICE and WHR system; which are control oriented. The control oriented models developed are based on applying the First and Second Laws of thermodynamics to the system. In particular, based on the of Thermodynamics. The designed XMPC framework maximizes the fuel conversion efficiency of the ICE by maximizing the second law efficiency of the ICE, turbocharger, heat exchanger, and organic Rankine cycle sub-systems in the integrated ICE and WHR system. In addition, the designed XMPC framework meets the exhaust gas temperature required by the exhaust aftertreatment systems. The results show that the application of designed XMPC framework to the integrated ICE and WHR system can reduce the fuel consumed by the ICE by 3.2%; compared to the application of a fully calibrated energy based rule based controller. •Novel exergy-wise model predictive control of engine and waste heat recovery system.•Studies an advanced dual fuel medium-duty engine.•Improves the fuel conversion efficiency of the engine.•Meets exhaust aftertreatment system temperature requirements.•Much less calibration efforts compared to conventional look-up table based engine control.
doi_str_mv	10.1016/j.conengprac.2023.105510
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subjects	Exergy based model predictive control Internal combustion engine Organic rankine cycle Waste heat recovery
title	Exergy based model predictive control of an integrated dual fuel engine and a waste heat recovery system
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