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Evaluating the influence of the compression ratio on the combustion process using methanol, gasoline, and methanol-gasoline blends

Ruobing Liu, Qi Cui, Hanyi Li, Haiyi Wang, Xixin Chen, Junhao Jin, Jinping Liu, Feng Zhou

2025Energy Reports7 citationsDOIOpen Access PDF

Abstract

In response to global energy and environmental challenges, this study systematically evaluates performance of methanol-gasoline blends (M100, M85) in comparison to pure gasoline in a spark-ignition (SI) engine. Through experimental data and numerical simulations, the combustion characteristics, energy flow distribution, and thermomechanical conversion processes of the three fuels were analyzed across compression ratios (CRs) ranging from 11 to 15. Under full-load conditions at 3500 r/min, gasoline showed 7.58 % and 8.69 % higher power outputs than M100 and M85, respectively. Additionally, when operating at the same speed under high loads (exceeding 125 Nm), methanol demonstrated better fuel economy than gasoline. This improvement stems from increased high-pressure cycle work, reduced heat transfer, and incomplete combustion losses. Both the effective expansion ratio (EER) and energy economy efficiency (EEE) peaked at a CR of approximately 13, beyond which efficiency gains plateaued while knock propensity intensified. Between 2500 and 3500 r/min with CR exceeding 13, methanol blends exhibited 18–23 % higher efficiency than gasoline, owing to their superior knock resistance resulting from greater octane sensitivity. The combustion characteristics of M85 fell between those of gasoline and M100, highlighting its potential as promising alternative fuel. These findings provide critical insights into enhancing methanol-gasoline engines through CR optimization, combustion phasing (CA50) calibration, and implementation of an effective thermal conversion process. The study systematically analyzes the combustion characteristics and energy flow synergy of high-proportion methanol-gasoline blends under high CR, along with the interactive effects of CR, load, and combustion timing. • The energy flow characteristics of the high-methanol blended fuel system under a high compression ratio are demonstrated under universal characteristic conditions.The interaction mechanism among compression ratio (CR), load, and combustion timing is clarified under universal characteristic conditions.(Split into two highlights.) • For different fuels, the energy economy efficiency shows an almost linear relationship with the effective expansion ratio under all compression ratios, providing a quantitative basis for the optimization of the combustion system. • The thermal energy of the methanol fuel is released more fully under the condition of a high compression ratio. • The fuel economies of the three fuels are basically the same under high load and high engine speed conditions.

Topics & Concepts

GasolineMethanolCombustionCompression ratioCompression (physics)Octane ratingProcess (computing)Waste managementMaterials scienceProcess engineeringChemical engineeringEnvironmental scienceChemistryOrganic chemistryComposite materialEngineeringComputer scienceOperating systemAdvanced Combustion Engine TechnologiesBiodiesel Production and ApplicationsHeat transfer and supercritical fluids