Multi-Objective Optimization of the Natural Gas-Air Venturi-Type Mixer for Bi-Fuel Engines

Salari, Mohammadali; Mohammadi, Rafat

doi:10.22044/jsfm.2025.15858.3944

Multi-Objective Optimization of the Natural Gas-Air Venturi-Type Mixer for Bi-Fuel Engines

Authors

¹ M.Sc., Mech. Eng., Arak Univ., Arak, Iran.

² Assoc. Prof., Mech. Eng., Arak Univ., Arak, Iran.

10.22044/jsfm.2025.15858.3944

Abstract

In the conversion of gasoline engines to natural gas, the mixer plays a crucial role in engine performance. This study presents a three-dimensional numerical simulation and geometric optimization of a natural gas-air Venturi-type mixer for a bi-fuel engine. The parametric study revealed that among the examined geometric parameters, increasing the number of orifices from 2 to 8 had the most significant impact, reducing the air-to-fuel ratio by 71% and increasing the uniformity index by 122.7%. Additionally, increasing the orifice diameter from 1 to 2.5 mm had a greater effect on the air-to-fuel ratio (44% decrease), while increasing the throat diameter from 17 to 20 mm had a greater effect on the uniformity index (17.9% decrease). A multi-objective genetic algorithm was employed to minimize deviations of the air-to-fuel ratio from the stoichiometric value and to maximize the uniformity index. The optimization results showed that in the geometry with the lowest deviation from the stoichiometric air-to-fuel ratio, this deviation and the uniformity index decreased by 99% and 39.7%, respectively, compared to the base-mode. Conversely, in the geometry with the highest uniformity index, this parameter increased by 16%, while the air-to-fuel ratio deviation increased by 32.6% relative to the base-mode.

Keywords

Main Subjects

Fluids Machines

References

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Volume 15, Issue 3
July and August 2025
Pages 165-182

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Multi-Objective Optimization of the Natural Gas-Air Venturi-Type Mixer for Bi-Fuel Engines

References

Volume 15, Issue 3
July and August 2025
Pages 165-182

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Multi-Objective Optimization of the Natural Gas-Air Venturi-Type Mixer for Bi-Fuel Engines

References

Volume 15, Issue 3July and August 2025Pages 165-182

Files

Share

How to cite

Statistics

Volume 15, Issue 3
July and August 2025
Pages 165-182