Abstract:
The low efficiency of the internal combustion engine has always been a virulent issue.
Researches are being carried out for decades to improve efficiency and eliminate
consequent problems. This study focuses on using computational fluid dynamics to
analyze the effect of inlet valve geometry and Spray angle on internal combustion
engines' performance. Computational fluid dynamics (CFD) analysis considers
snapshots of fuel flow in internal combustion at critical points. Combustion efficiency
is affected by phenomena like swirl and tumble. CFD analysis is used to study these
phenomena. It considers the role of intake port geometry and sprays angles in creating
squish and swirl. Phenomena like swirl and tumble are vital to combustion of fuel,
increasing the efficiency of combustion and engine overall performance. In the study,
CFD is being utilized to verify an experimental study with ANSYS fluent solver. The
results are being compared to the experimental values of the previous study. The
information predicted by Fluent is being discussed. This study analyzes the variation
of flow parameters like pressure, temperature, and velocity using the finite volume
method (FVM) solver with the standard k-ε turbulence model in computational fluid
dynamics (CFD) with different spray angles. Geometry has been designed using
Design Modeler and CFD analysis of injection has been carried out using ANSYS
Fluent. Four different cases were applied to all the designs to investigate the
performance. Based on the standard performance parameters available in the literature,
Parameters with better performance were selected. The best design was further
validated with the existing design in the literature by giving the same boundary
conditions. This study's design has shown better performance in all parameters than
the design available in the literature
