RE-ENGINEERING OF THE AIR INTAKE MANIFOLD FOR UTP FORMULA CAR

Muharnad, Dzulkarnain (2008) RE-ENGINEERING OF THE AIR INTAKE MANIFOLD FOR UTP FORMULA CAR. [Final Year Project] (Unpublished)

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Abstract

Formula SAE (Society of Automotive Engineers) is a car racing competition whereby the
competitors have to design and fabricate the vehicle. The racing car must have a powerful
engine that generates the highest possible amount of power and torque within a specified
range of speed. To meet this condition, the engine must have a good breathing system
where it demands sufficient quality of air and fuel flow into the engine. This is where and
why the effect of the air intake manifold is significant to the engine performance.
Previous UTP FSAE car in 2006 experienced inefficient engine combustion due to
inadequate air intake while the engine was running. The present research project is about
the improvement of the air intake manifold for Formula SAE car UTP Team 2008. The
I .
objective of the project is to modifY the design of the air intake system ill order to provide
"
optimum volume of air flow and best volumetric efficiency into the engine. The major
challenge in this project is to design it according to the SAE Rules and Regulations.
Among others; the regulations specifY a limit of power capacity of the engine, while a
single 20 mm circular restrictor must be placed in the intake system between the throttle
body and the engine, and that all engine airflow must pass through the restrictor. The
restriction will obviously reduce the engine's total performance. The methodology of this
project is by applying the "Helmholtz Resonance Theory" to calculate appropriate length
of the intake manifold and for the purpose of tuning of the manifold with the engine. This
is done mathematically and the result is obtained by dynamometer test in order to prove
the theory. This is followed by design of air intake manifold will be design by using Solid
Works software and flow simulation using Fluent 6.1.
IV

Item Type: Final Year Project
Subjects: T Technology > TJ Mechanical engineering and machinery
Departments / MOR / COE: Engineering > Mechanical
Depositing User: Users 2053 not found.
Date Deposited: 29 Oct 2013 10:49
Last Modified: 25 Jan 2017 09:44
URI: http://utpedia.utp.edu.my/id/eprint/10015

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