Strategies to Form Homogeneous Mixture and Methods to Control Auto-Ignition of HCCI Engine

Ibham Veza,Mohd Rozi Mohd Perang,Mohd Farid Muhamad Said,T.w.b Riyadi T.W.B Riyadi,N Tamaldin N Tamaldin,Zulkarnain Abdul Latiff,Hoon Kiat Ng,A Sule A Sule,Mohd Azman Abas

doi:10.15282/ijame.18.4.2021.09.0712

Abstract

Homogeneous charge compression ignition (HCCI) engine has emerged as a promising combustion technology. Theoretically, an HCCI engine can reduce both NOx and soot emissions significantly down to almost zero levels. This is possible as a result of two fundamental processes that occur in the HCCI engine, i.e. the homogeneous mixture and its autoignition characteristics. Neither spark plug nor injector is used in the HCCI engine. The autoignition of the homogeneous mixture is solely influenced by its chemical reactions inside the combustion chamber. However, this is where the problems start to occur. At low loads or too lean mixtures, misfire may occur, thus increasing the HC and CO emissions. At high loads or too rich mixtures, soot emissions and knocking tendency may increase. Moreover, an undesirable pressure rise due to knocking will increase the combustion temperature and potentially increase the probability of NOx formation. Therefore, the operating range of HCCI engine is very limited only to part loads. Controlling its combustion phasing play an important role to extend the narrow operating range of the HCCI engine. Despite numerous review articles have been published, classification of the approaches to achieve HCCI combustion in diesel engines were rarely presented clearly. Therefore, this review article aims to provide a concise and comprehensive classification of HCCI combustion so that the role and position of each strategy found in the literature could be understood distinctively. In short, two important questions must be solved to have successful HCCI combustion; (1) how to form a homogeneous mixture? and (2) how to control its auto-ignition?

Highlights

As emission regulation is increasingly stricter throughout the world, research and development towards cleaner and more efficient engines are extensively conducted [1-4]
The results showed that 5 bar injection pressure and 60 oC air temperature was able to achieve the brake thermal efficiency comparable to that of a conventional diesel engine, with both NOx and smoke emissions being reduced significantly
This study indicates that the time of ignition of the Homogeneous charge compression ignition (HCCI) engine can be controlled by maintaining constant value other engine parameters such as the load, speed, pressure and intake air temperature

Summary

Introduction

As emission regulation is increasingly stricter throughout the world, research and development towards cleaner and more efficient engines are extensively conducted [1-4]. The diesel engine is currently considered as one of the lowest well-to-wheel CO2 system owing to the development of high-pressure common-rail direct injection [14, 15]. It suffers from the trade of NOx and PM emissions [1622]. Numerous after-treatment technologies have been proposed, including Diesel Particle Filters (DPF) [29-38], Selective Catalytic Reduction (SCR) [39-46] and Diesel Oxidation Catalyst (DOC) [47-52]. These methods have been successfully applied to reduce harmful emissions in diesel engines. Despite being very effective to reduce emissions of diesel engines, the use of exhaust aftertreatment devices will add the production cost of a vehicle, making it uneconomically feasible [53]

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Conclusion