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Lemon peel oil as an alternative fuel for GDI engines: A spray characterization perspective

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  • Biswal, Abinash
  • Kale, Rakesh
  • Balusamy, Saravanan
  • Banerjee, Raja
  • Kolhe, Pankaj

Abstract

Lemon peel oil (LPO: C10H16O0.082) shows very similar calorific value, stoichiometric air to fuel ratio as isooctane, an ideal reference fuel for a gasoline engine, and also possesses very good anti-knock tendency and octane number rating (RON = 80) making it possible alternative fuel for gasoline engines. The present study investigates the suitability of LPO for direct injection spark ignition application by contrasting the spray characteristics of LPO with reference fuel isooctane for simulated engine-like conditions. Experiments were performed in a constant volume spray chamber under various engine-like pressure and temperature conditions. A six-hole GDI injector was used to study the spray behavior of LPO and then compared to standard reference fuel, isooctane. The ambient conditions in the chamber were derived using the crank resolved pressure data of the GDI engine. The selected chamber conditions are a) 1.5 bar, 329 K; b) 2.5 bar, 371 K; c) 6.0 bar, 453 K simulating in-cylinder conditions for three different injection timings. Phase Doppler particle analyzer and Mie scatter imaging techniques were employed for spray characterization. Spray morphology along with joint probability distribution for droplet size and axial velocity, cumulative volume fraction and Weber and Reynolds number ranges were used to contrast the two sprays for LPO and isooctane. Results showed that ambient pressure and temperature have a significant effect on spray behavior and late injection in compression stroke is proposed to be ideal for LPO to match the engine performance with that of isooctane based on the spray quality comparison.

Suggested Citation

  • Biswal, Abinash & Kale, Rakesh & Balusamy, Saravanan & Banerjee, Raja & Kolhe, Pankaj, 2019. "Lemon peel oil as an alternative fuel for GDI engines: A spray characterization perspective," Renewable Energy, Elsevier, vol. 142(C), pages 249-263.
    • Handle: RePEc:eee:renene:v:142:y:2019:i:c:p:249-263
    DOI: 10.1016/j.renene.2019.04.087
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