ScholarWorks@경상국립대학교

초록

This work provides a systematic evaluation of the performance and regulated emissions of binary n-pentanol-diesel blends under steady-state conditions, thereby clarifying condition-dependent efficiency-emission trade-offs across multiple loads and speeds. A single-cylinder, air-cooled diesel engine was operated at two speeds (1700 and 2700 rpm) and four brake mean effective pressure (BMEP) levels (0.25-0.49 MPa) using commercial diesel (D100) and three n-pentanol-diesel blends at volume ratios of 10%, 30%, and 50% (designated D90P10, D70P30, and D50P50, respectively). Brake thermal efficiency (BTE), brake specific energy consumption (BSEC), and brake specific fuel consumption (BSFC) were measured alongside exhaust emissions of nitrogen oxides (NOx), carbon monoxide (CO), hydrocarbon (HC), carbon dioxide (CO2), and smoke opacity. The results show that due to a lower cetane number, high latent heat of vaporization, and reduced heating value, n-pentanol blends incur efficiency and fuel consumption penalties at light to moderate loads. However, these disadvantages diminish or reverse at high loads and speeds: D50P50 surpasses D100 in BTE and matches or improves BSEC and BSFC at 2700 rpm and 0.49 MPa. Emission data reveal that the blend's fuel-bound oxygen and enhanced mixing provide up to 16% NOx reduction; 35% and 45% reductions in CO and HC, respectively; and a 74% reduction in smoke opacity under demanding conditions, while CO2 per unit work output aligns with or falls below D100 at high load. These findings demonstrate that optimized n-pentanol-diesel blends can simultaneously improve efficiency and mitigate emissions, offering a practical pathway for low-carbon diesel engines.

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