Abstract
Small diesel generators (< 10-kilowatt (kW) electricity output) are widely used as primary and backup sources of electricity in remote and other off-grid communities in Canada owing to their portability and durability. Major challenges associated with these generators include high costs of diesel and its transportation, as well as greenhouse gas (GHG) emissions. Biogas, which can be produced from the local waste or biomass, can be introduced into a diesel generator to potentially reduce diesel consumption and GHG emissions. The objective of this experimental study is to investigate the impact of engine speed, biogas composition, and intake temperature on the performance of a small biogasdiesel dual-fuel generator.
This study was conducted using a 4-kW diesel generator with a normally aspirated, four-stroke, direct injection, single-cylinder diesel engine. A new intake manifold was installed on the engine to incorporate a biogas dosing port. The biogas was simulated by a mixture of compressed natural gas (composed of more than 95% methane), carbon dioxide (CO2), and nitrogen (N2). Exhaust gas temperature and composition were also recorded. Electrical load was maintained at 3.1 kW.
The results of this study indicated that raising the engine speed from 1800 to 3600 rpm increased the diesel consumption rate, thereby increasing the overall GHG emissions. However, NOx emissions were reduced. The impact of the biogas composition was significant, especially the effect of CO2 when compared to N2. Increasing intake temperature improved engine efficiency particularly at higher biogas flow rates. The results highlighted the challenges associated with the application of biogas-diesel dual-fuel technology in small diesel generators with highspeed engines.