International Journal of Vehicle Structures and Systems

Open Access Open Access  Restricted Access Subscription Access

Finite Element Simulation for Improved Design of Plastic Intake Manifold for Four Cylinder Engines


Affiliations
1 Qingdao Agricultural University, Qingdao, Shandong, China
 

   Subscribe/Renew Journal


In order to reduce the weight for improving fuel efficiency and enhance the performance of automobile engines, research into plastic manifolds compared to conventional aluminium and iron manifolds is becoming a trend for the intake structure design. In this paper, finite element simulation is employed to design and optimize a plastic manifold for a four cylinder intake structure. The yield strength of intake manifold structure for an applied burst pressure of 6.5bar is verified using finite element analysis. Based on the simulation results and identification of strength critical zones, stiffeners were introduced to improve the plastic intake manifold design for an operational temperature range of 20-120 degrees Celsius.

Keywords

Plastic Intake Manifold, Structure Design, Yield Strength, Optimization.
User
Subscription Login to verify subscription
Notifications
Font Size

Abstract Views: 220

PDF Views: 130




  • Finite Element Simulation for Improved Design of Plastic Intake Manifold for Four Cylinder Engines

Abstract Views: 220  |  PDF Views: 130

Authors

Zhang Xinjie
Qingdao Agricultural University, Qingdao, Shandong, China

Abstract


In order to reduce the weight for improving fuel efficiency and enhance the performance of automobile engines, research into plastic manifolds compared to conventional aluminium and iron manifolds is becoming a trend for the intake structure design. In this paper, finite element simulation is employed to design and optimize a plastic manifold for a four cylinder intake structure. The yield strength of intake manifold structure for an applied burst pressure of 6.5bar is verified using finite element analysis. Based on the simulation results and identification of strength critical zones, stiffeners were introduced to improve the plastic intake manifold design for an operational temperature range of 20-120 degrees Celsius.

Keywords


Plastic Intake Manifold, Structure Design, Yield Strength, Optimization.



DOI: https://doi.org/10.4273/ijvss.5.3-4.05