What question did this study set out to answer?

The research aims to enhance diesel engine performance by optimizing combustion characteristics using e-fuel and advanced timing techniques.

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March 26, 2026Open Access

Numerical analysis of combustion characteristics in a diesel engine using e-fuel

Key Points

The research aims to enhance diesel engine performance by optimizing combustion characteristics using e-fuel and advanced timing techniques.
Utilized 3DCFD tool ANSYS Forte for surrogate modeling of e-fuel
Investigated effects of Late Intake Valve Closing (LIVC) under PCCI combustion
Examined the role of Exhaust Gas Recirculation (EGR) on combustion emissions
Retarding ignition timing through LIVC improved thermal efficiency and indicated mean effective pressure (IMEP)
NOx emissions were reduced after improving ignition timing with LIVC
Further reductions in NOx emissions were achieved with the implementation of EGR

Abstract

Due to the difference in cetane number between e-fuel, a synthetic fuel made from CO2, and diesel, pre-ignition is an issue in PCCI combustion, where the fuel is sprayed early. Therefore, we aimed to lower the effective compression ratio and retard the ignition timing by using LIVC (Late Intake Valve Closing) with a VVT mechanism. We created a surrogate model of e-fuel using the 3DCFD tool ANSYS Forte and investigated the effects of LIVC and the presence or absence of EGR under PCCI combustion conditions. As a result, when LIVC was performed, the ignition timing was retarded, improving engine performance such as thermal efficiency and IMEP. Furthermore, NOx emissions could be reduced by improving the ignition timing. We also found that further reductions in NOx emissions could be achieved by using EGR.

Numerical analysis of combustion characteristics in a diesel engine using e-fuel

Key Points

Abstract

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