Multiphysics performance assessment of hydrogen fuelled engines

In the quest for decarbonisation, alternative clean fuels for propulsion systems are sought. There is definite advantage in retaining the well-established principles of operation of combustion engines at the core of future developments with hydrogen as a fuel. Hydrogen is envisaged as a clean source...

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Veröffentlicht in:	International journal of engine research 2023-09, Vol.24 (9), p.4169-4189
Hauptverfasser:	Rahmani, Ramin, Dolatabadi, Nader, Rahnejat, Homer
Format:	Artikel
Sprache:	eng
Schlagworte:	Additives Clean energy Clean fuels Cylinders Degradation Dilution Durability Energy sources Engines Hydrogen Hydrogen combustion Internal combustion engines Lubricants & lubrication Off road vehicles Performance assessment Principles Propulsion systems Tribology
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container_title	International journal of engine research
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creator	Rahmani, Ramin Dolatabadi, Nader Rahnejat, Homer
description	In the quest for decarbonisation, alternative clean fuels for propulsion systems are sought. There is definite advantage in retaining the well-established principles of operation of combustion engines at the core of future developments with hydrogen as a fuel. Hydrogen is envisaged as a clean source of energy for propulsion of heavy and off-road vehicles, as well as in marine and construction sectors. A source of concern is the unexplored effect of hydrogen combustion on dilution and degradation of engine lubricants and their additives, and consequently upon tribology of engine contact conjunctions. These potential problems can adversely affect engine efficiency, durability, and operational integrity. Use of different fuels and their method of delivery, produces distinctive combustion characteristics that can affect the energy losses associated with in-cylinder components and their durability. Therefore, detailed predictive analysis should support the developments of such new generation of eco-friendly engines. Different fundamental physics underpin the various aspects of a pertinent detailed analysis. These include thermodynamics of combustion, in-cylinder tribological interactions of contacting surfaces, and blowby of generated gasses. This paper presents such an integrated multi-physics analysis of internal combustion engines with focus on hydrogen as the fuel. Such an in-depth and computationally efficient analysis has not hitherto been reported in the literature. The results show implications for lubricant degradation due to the use of hydrogen in the performance of in-cylinder components and the underlying physical principles.
doi_str_mv	10.1177/14680874231182211
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Different fundamental physics underpin the various aspects of a pertinent detailed analysis. These include thermodynamics of combustion, in-cylinder tribological interactions of contacting surfaces, and blowby of generated gasses. This paper presents such an integrated multi-physics analysis of internal combustion engines with focus on hydrogen as the fuel. Such an in-depth and computationally efficient analysis has not hitherto been reported in the literature. 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subjects	Additives Clean energy Clean fuels Cylinders Degradation Dilution Durability Energy sources Engines Hydrogen Hydrogen combustion Internal combustion engines Lubricants & lubrication Off road vehicles Performance assessment Principles Propulsion systems Tribology
title	Multiphysics performance assessment of hydrogen fuelled engines
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