SIMULATION OF THE EFFECT OF INJECTION PRESSURE, INJECTION HOLE DIAMETER, AND COMBUSTION CHAMBER PRESSURE ON INJECTION SPEED AND DROPLET DIAMETER OF DIESEL FUEL
Diesel motors are known for their tough and high-efficiency motors. Optimal performance of the diesel engine requires precise settings, especially in the process of mixing the fuel coming out of the injector and the pressure of the combustion chamber. This study simulates the injection pressure,...
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| Format: | Final Project |
| Language: | Indonesia |
| Online Access: | https://digilib.itb.ac.id/gdl/view/61769 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | Diesel motors are known for their tough and high-efficiency motors. Optimal
performance of the diesel engine requires precise settings, especially in the process of mixing
the fuel coming out of the injector and the pressure of the combustion chamber. This study
simulates the injection pressure, injection hole diameter, and combustion chamber pressure
using ANSYS Fluent software with 2 dimension of combution chamber and KHRT method
for droplet model. The test parameters were taken are the injection speed, droplet diameter
(average diameter, minimum diameter, critical diameter, and time to reach the critical
diameter).
The results showed that higher injection pressure make the injection speed faster, the
droplet diameter smaller, and the time to reach the critical diameter shorter. Larger injection
hole diameter make the injection speed slower, the droplet diameter larger, and the time to
reach the critical diameter longer. Higher combustion chamber pressure make the injection
speed slower, the droplet diameter larger, and the time to reach the critical diameter longer.
Different results were found at injection pressures of 150 MPa, 180 MPa, and 210 MPa,
especially the minimum droplet diameter and critical droplet diameter parameters were not
in accordance with the existing theory. This is influenced by the high injection speed and the
large initial diameter of the droplet so the drag force that occurs is bigger which causes the
droplets to be more easily split.
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